Cisco ONS 15454 SDH Reference Manual Product and Documentation Release 5.0 Last Updated: April 2009 Corporate Headquarters Cisco Systems, Inc. 170 West Tasman Drive San Jose, CA 95134-1706 USA http://www.cisco.
THE SPECIFICATIONS AND INFORMATION REGARDING THE PRODUCTS IN THIS MANUAL ARE SUBJECT TO CHANGE WITHOUT NOTICE. ALL STATEMENTS, INFORMATION, AND RECOMMENDATIONS IN THIS MANUAL ARE BELIEVED TO BE ACCURATE BUT ARE PRESENTED WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED. USERS MUST TAKE FULL RESPONSIBILITY FOR THEIR APPLICATION OF ANY PRODUCTS.
CONTENTS About this Guide xxix Revision History xxix Document Objectives Audience xxx xxx Document Organization xxx Related Documentation xxxi Document Conventions xxxi Obtaining Optical Networking Information xxxviii Where to Find Safety and Warning Information xxxviii Cisco Optical Networking Product Documentation CD-ROM Obtaining Documentation and Submitting a Service Request CHAPTER 1 Shelf and FMEC Hardware 1.1 Overview 1.2 Front Door xxxviii xxxviii 1-1 1-1 1-3 1.
Contents CHAPTER 2 Common Control Cards 2-1 2.1 Common Control Card Overview 2-1 2.1.1 Card Summary 2-1 2.1.2 Card Compatibility 2-2 2.1.3 Cross-Connect Card Compatibility 2-3 2.2 TCC2 Card 2-4 2.2.1 TCC2 Card Functionality 2-6 2.2.2 TCC2 Card-Level Indicators 2-6 2.2.3 Network-Level Indicators 2-7 2.3 TCC2P Card 2-7 2.3.1 TCC2P Functionality 2-8 2.3.2 TCC2P Card-Level Indicators 2-9 2.3.3 Network-Level Indicators 2-10 2.4 XC10G Card 2-10 2.4.1 XC10G Functionality 2-12 2.4.
Contents 3.3 E1-42 Card 3-6 3.3.1 E1-42 Card Functionality 3-7 3.3.2 E1-42 Card-Level Indicators 3-8 3.3.3 E1-42 Port-Level Indicators 3-8 3.4 E3-12 Card 3-8 3.4.1 E3-12 Card Functionality 3-9 3.4.2 E3-12 Card-Level Indicators 3-10 3.4.3 E3-12 Port-Level Indicators 3-10 3.5 DS3i-N-12 Card 3-10 3.5.1 DS3i-N-12 Card Functionality 3-11 3.5.2 DS3i-N-12 Card-Level Indicators 3-12 3.5.3 DS3i-N-12 Port-Level Indicators 3-12 3.6 STM1E-12 Card 3-13 3.6.1 STM 1E-12 Card Functionality 3-13 3.6.
Contents 4.1.1 Card Summary 4-2 4.1.2 Card Compatibility 4-3 4.2 OC3 IR 4/STM1 SH 1310 Card 4-4 4.2.1 OC3 IR 4/STM1 SH 1310 Functionality 4-6 4.2.2 OC3 IR 4/STM1 SH 1310 Card-Level Indicators 4-7 4.2.3 OC3 IR 4/STM1 SH 1310 Port-Level Indicators 4-7 4.3 OC3 IR/STM1 SH 1310-8 Card 4-7 4.3.1 OC3 IR/STM1 SH 1310-8 Card-Level Indicators 4-10 4.3.2 OC3 IR/STM1 SH 1310-8 Port-Level Indicators 4-10 4.4 OC12 IR/STM4 SH 1310 Card 4-11 4.4.1 OC12 IR/STM4 SH 1310 Card-Level Indicators 4-12 4.4.
Contents 4.12 OC192 IR/STM64 SH 1550 Card 4-32 4.12.1 OC192 IR/STM64 SH 1550 Card Functionality 4-34 4.12.2 OC192 IR/STM64 SH 1550 Card-Level Indicators 4-35 4.12.3 OC192 IR/STM64 SH 1550 Port-Level Indicators 4-35 4.13 OC192 LR/STM64 LH 1550 Card 4-35 4.13.1 OC192 LR/STM64 LH 1550 Card Functionality 4-37 4.13.2 OC192 LR/STM64 LH 1550 Card-Level Indicators 4-38 4.13.3 OC192 LR/STM64 LH 1550 Port-Level Indicators 4-38 4.14 OC192 LR/STM64 LH ITU 15xx.xx Card 4-39 4.14.1 OC192 LR/STM64 LH ITU 15xx.
Contents 5.7.2 ML1000-2 Port-Level Indicators 5-14 5.7.3 ML1000-2 Slot Compatibility 5-14 5.8 GBICs and SFPs 5-14 5.8.1 Compatibility by Card 5-15 5.8.2 GBIC Description 5-15 5.8.2.1 DWDM and CWDM GBICs 5.8.3 SFP Description 5-18 CHAPTER 6 Storage Access Networking Cards 5-16 6-1 6.1 FC_MR-4 Card Overview 6-1 6.1.1 FC_MR-4 Card-Level Indicators 6-2 6.1.2 FC_MR-4 Port-Level Indicators 6-3 6.1.3 FC_MR-4 Compatibility 6-3 6.2 FC_MR-4 Card Modes 6-3 6.2.1 Line-Rate Card Mode 6-3 6.2.
Contents 8.2 CTC Installation Overview 8-3 8.3 PC and UNIX Workstation Requirements 8.4 ONS 15454 SDH Connection 8-5 8.5 CTC Window 8-6 8.5.1 Node View 8-7 8.5.1.1 CTC Card Colors 8-7 8.5.1.2 Node View Card Shortcuts 8.5.1.3 Node View Tabs 8-10 8.5.2 Network View 8-11 8.5.3 Card View 8-13 8.6 TCC2/TCC2P Card Reset CHAPTER 9 Security and Timing 8-10 8-15 8.7 TCC2/TCC2P Card Database 8.8 Software Revert 8-3 8-15 8-15 9-1 9.1 Users and Security 9-1 9.1.1 Security Requirements 9-1 9.1.
Contents 10.7 SNCP Circuits 10-12 10.7.1 Open-Ended SNCP Circuits 10-13 10.7.2 Go-and-Return SNCP Routing 10-13 10.8 MS-SPRing Protection Channel Access Circuits 10.9 Path Trace 10-14 10-15 10.10 Path Signal Label, C2 Byte 10-15 10.11 Automatic Circuit Routing 10-16 10.11.1 Bandwidth Allocation and Routing 10-17 10.11.2 Secondary Sources and Destinations 10-17 10.12 Manual Circuit Routing 10-18 10.13 Constraint-Based Circuit Routing 10-22 10.14 Virtual Concatenated Circuits 10-22 10.14.
Contents 11.9.1 Span Upgrade Wizard 11-32 11.9.2 Manual Span Upgrades 11-32 CHAPTER 12 CTC Network Connectivity 12-1 12.1 IP Networking Overview 12-1 12.2 IP Addressing Scenarios 12-2 12.2.1 Scenario 1: CTC and ONS 15454 SDH Nodes on Same Subnet 12-2 12.2.2 Scenario 2: CTC and ONS 15454 SDH Nodes Connected to a Router 12-3 12.2.3 Scenario 3: Using Proxy ARP to Enable an ONS 15454 SDH Gateway 12-4 12.2.4 Scenario 4: Default Gateway on CTC Computer 12-6 12.2.
Contents 13.6 Alarm Profiles 13-10 13.6.1 Creating and Modifying Alarm Profiles 13.6.2 Alarm Profile Buttons 13-12 13.6.3 Alarm Profile Editing 13-12 13.6.4 Alarm Severity Options 13-12 13.6.5 Row Display Options 13-13 13.6.6 Applying Alarm Profiles 13-13 13.7 Suppressing Alarms 13-11 13-14 13.8 Provisioning External Alarms and Controls 13.8.1 External Alarm Input 13-15 13.8.2 External Control Output 13-15 13-15 13.9 Audit Trail 13-16 13.9.1 Audit Trail Log Entries 13-16 13.9.
Contents 14.3.6.3 E-Series Spanning Tree Parameters 14-18 14.3.6.4 E-Series Spanning Tree Configuration 14-18 14.4 G-Series Circuit Configurations 14-19 14.4.1 G-Series Point-to-Point Ethernet Circuits 14-19 14.4.2 G-Series Manual Cross-Connects 14-19 14.5 E-Series Circuit Configurations 14-20 14.5.1 Port-Mapped Mode and Single-card EtherSwitch Circuit Scenarios 14.5.2 E-Series Point-to-Point Ethernet Circuits 14-21 14.5.3 E-Series Shared Packet Ring Ethernet Circuits 14-22 14.5.
Contents A.5.2 E1-42 Card Specifications A-13 A.5.3 E3-12 Card Specifications A-14 A.5.4 DS3i-N-12 Card Specifications A-15 A.5.5 STM1E-12 Card Specifications A-16 A.5.6 BLANK Card A-17 A.5.7 FMEC-E1 Specifications A-17 A.5.8 FMEC-DS1/E1 Card Specifications A-18 A.5.9 FMEC E1-120NP Card Specifications A-18 A.5.10 FMEC E1-120PROA Card Specifications A-19 A.5.11 FMEC E1-120PROB Card Specifications A-20 A.5.12 E1-75/120 Impedance Conversion Panel Specifications A.5.13 FMEC-E3/DS3 Card Specifications A-21 A.5.
Contents APPENDIX B Administrative and Service States B.1 Service States B-1 B-1 B.2 Administrative States B-2 B.3 Service State Transitions B-3 B.3.1 Card Service State Transitions B-3 B.3.2 Port and Cross-Connect Service State Transitions APPENDIX C Network Element Defaults B-5 C-1 C.1 Network Element Defaults Description C-1 C.2 Card Default Settings C-1 C.2.1 E1 Card Default Settings C-3 C.2.2 E1-42 Card Default Settings C-4 C.2.3 E3 Card Default Settings C-6 C.2.
Contents Cisco ONS 15454 SDH Reference Manual, R5.
F I G U R E S Figure 1-1 ONS 15454 SDH Dimensions Figure 1-2 The ONS 15454 SDH Front Door Figure 1-3 Removing the ONS 15454 SDH Front Door Figure 1-4 Front-Door Erasable Label Figure 1-5 Laser Warning on the Front-Door Label Figure 1-6 Mounting the E1-75/120 Conversion Panel in a Rack Figure 1-7 Managing Cables on the Front Panel Figure 1-8 Fiber Capacity Figure 1-9 Position of the Fan-Tray Assembly Figure 1-10 Installing Cards in the ONS 15454 SDH Figure 2-1 TCC2 Faceplate and Block D
Figures Figure 3-12 E1-75/120 Impedance Conversion Panel Faceplate Figure 3-13 E1-75/120 with Optional Rackmount Brackets Figure 3-14 E1-75/120 Impedance Conversion Panel Block Diagram Figure 3-15 FMEC-E3/DS3 Faceplate and Block Diagram Figure 3-16 FMEC STM1E 1:1 Faceplate and Block Diagram Figure 3-17 FMEC-BLANK Faceplate Figure 3-18 MIC-A/P Faceplate and Block Diagram Figure 3-19 MIC-C/T/P Faceplate and Block Diagram Figure 4-1 OC3 IR 4/STM1 SH 1310 Faceplate Figure 4-2 OC3 IR 4/STM1 S
Figures Figure 5-4 G1K-4 Faceplate and Block Diagram Figure 5-5 ML100T-12 Faceplate Figure 5-6 ML1000-2 Faceplate Figure 5-7 GBICs with Clips (left) and with a Handle (right) Figure 5-8 CWDM GBIC with Wavelength Appropriate for Fiber-Connected Device Figure 5-9 G-Series with CWDM/DWDM GBICs in Cable Network Figure 5-10 Mylar Tab SFP Figure 5-11 Actuator/Button SFP Figure 5-12 Bail Clasp SFP Figure 6-1 FC_MR-4 Faceplate and Block Diagram Figure 7-1 ONS 15454 SDH Cards in a 1:1 Protectio
Figures Figure 11-4 Four-Node, Four-Fiber MS-SPRing Figure 11-5 Four-Fiber MS-SPRing Span Switch Figure 11-6 Four-Fiber MS-SPRing Switch 11-8 Figure 11-7 MS-SPRing Bandwidth Reuse 11-9 Figure 11-8 Five-Node, Two-Fiber MS-SPRing Figure 11-9 Shelf Assembly Layout for Node 0 in Figure 11-8 Figure 11-10 Shelf Assembly Layout for Nodes 1 to 4 in Figure 11-8 Figure 11-11 Connecting Fiber to a Four-Node, Two-Fiber MS-SPRing 11-12 Figure 11-12 Connecting Fiber to a Four-Node, Four-Fiber MS-SPRi
Figures Figure 12-9 Scenario 6: OSPF Not Enabled Figure 12-10 Proxy Server Gateway Settings Figure 12-11 Scenario 7: SDH Proxy Server with GNE and ENEs on the Same Subnet Figure 12-12 Scenario 7: ONS 15454 SDH Proxy Server with GNE and ENEs on Different Subnets Figure 12-13 Scenario 7: ONS 15454 SDH Proxy Server With ENEs on Multiple Rings Figure 12-14 Scenario 8: Dual GNEs on the Same Subnet 12-18 Figure 12-15 Scenario 8: Dual GNEs on Different Subnets 12-19 Figure 12-16 Scenario 9: ONS 1
Figures Figure 14-21 Hub-and-Spoke Ethernet Circuit 14-23 Cisco ONS 15454 SDH Reference Manual, R5.
T A B L E S Table 1 Cisco ONS 15454 SDH Reference Manual Chapters Table 1-1 Slot and FMEC Symbols Table 1-2 FMEC, Ports, Line Rates, and Connectors Table 1-3 Fiber Channel Capacity (One Side of the Shelf) Table 1-4 Slot and Card Symbols Table 1-5 Card Ports, Line Rates, and Connectors Table 1-6 ONS 15454 SDH Software Release/Hardware Compatibility—XC-VXL-2.
Tables Table 3-7 STM1E-12 Card-Level Indicators Table 3-8 E-1 Interface Pinouts on Ports 1 to 7 Table 3-9 E-1 Interface Pinouts on Ports 8 to 14 3-17 Table 3-10 E-1 Interface Pinouts on Ports 1 to 21 3-19 Table 3-11 E-1 Interface Pinouts on Ports 22 to 42 Table 3-12 E-1 Interface Pinouts on Ports 1 to 21 Table 3-13 E-1 Interface Pinouts on Ports 22 to 42 Table 3-14 E-1 Interface Pinouts on Ports 1 to 21 Table 3-15 E-1 Interface Pinouts on Ports 22 to 42 Table 3-16 Alarm Interface Pinou
Tables Table 5-11 ML100T-12 Card-Level Indicators 5-12 Table 5-12 ML100T-12 Port-Level Indicators 5-12 Table 5-13 ML1000-2 Card-Level Indicators 5-14 Table 5-14 ML1000-2 Port-Level Indicators 5-14 Table 5-15 GBIC and SFP Card Compatibility Table 5-16 Supported Wavelengths for CWDM GBICs 5-17 Table 5-17 Supported Wavelengths for DWDM GBICs 5-17 Table 6-1 FC_MR-4 Card-Level Indicators Table 8-1 JRE Compatibility Table 8-2 CTC Computer Requirements Table 8-3 ONS 15454 SDH Connection
Tables Table 10-11 Bidirectional Low-Order Tunnels Table 10-12 ONS 15454 SDH Card VCAT Circuit Rates and Members Table 10-13 ONS 15454 SDH VCAT Card Capabilities Table 11-1 ONS 15454 SDH Rings with Redundant TCC2/TCC2P Cards Table 11-2 Two-Fiber MS-SPRing Capacity 11-8 Table 11-3 Four-Fiber MS-SPRing Capacity 11-9 Table 12-1 General ONS 15454 SDH IP Troubleshooting Checklist Table 12-2 ONS 15454 SDH Gateway and Element NE Settings Table 12-3 Proxy Server Firewall Filtering Rules Table 1
Tables Table B-5 ONS 15454 SDH Port and Cross-Connect Service State Transitions Table C-1 E1 Card Default Settings Table C-2 E1-42 Card Default Settings Table C-3 E3 Card Default Settings Table C-4 FC-MR Card Default Settings Table C-5 DS3I Card Default Settings C-8 Table C-6 Data Card Default Settings C-11 Table C-7 STM1 Card Default Settings Table C-8 STM1-8 Card Default Settings Table C-9 STM1E-12 Card Default Settings Table C-10 STM4 Card Default Settings Table C-11 STM4-4 Card
Tables Cisco ONS 15454 SDH Reference Manual, R5.
About this Guide Note The terms “Unidirectional Path Switched Ring” and “UPSR” may appear in Cisco literature. These terms do not refer to using Cisco ONS 15xxx products in a unidirectional path switched ring configuration. Rather, these terms, as well as “Path Protected Mesh Network” and “PPMN,” refer generally to Cisco’s path protection feature, which may be used in any topological network configuration.
About this Guide Document Objectives This manual provides reference information for the Cisco ONS 15454 SDH. Audience To use this publication, you should be familiar with Cisco or equivalent optical transmission hardware and cabling, telecommunications hardware and cabling, electronic circuitry and wiring practices, and preferably have experience as a telecommunications technician. Document Organization Table 1 lists the chapter titles and provides a summary for each chapter.
About this Guide Table 1 Cisco ONS 15454 SDH Reference Manual Chapters (continued) Title Summary Chapter 10, “Circuits and Tunnels” Includes descriptions of circuit properties, cross-connect card bandwidth usage, data communications channel (DCC) and IP-encapsulated tunnels, multiple destination circuits, circuit monitoring, subnetwork connection protection (SNCP) and multiplex section-shared protection rings (MS-SPRing) circuits, J1 path trace, path signal labels, manual and automatic circuit routing
About this Guide Convention Application boldface Commands and keywords in body text. italic Command input that is supplied by the user. [ Keywords or arguments that appear within square brackets are optional. ] {x|x|x} A choice of keywords (represented by x) appears in braces separated by vertical bars. The user must select one. Ctrl The control key. For example, where Ctrl + D is written, hold down the Control key while pressing the D key.
About this Guide Warning IMPORTANT SAFETY INSTRUCTIONS This warning symbol means danger. You are in a situation that could cause bodily injury. Before you work on any equipment, be aware of the hazards involved with electrical circuitry and be familiar with standard practices for preventing accidents. Use the statement number provided at the end of each warning to locate its translation in the translated safety warnings that accompanied this device.
About this Guide Avvertenza IMPORTANTI ISTRUZIONI SULLA SICUREZZA Questo simbolo di avvertenza indica un pericolo. La situazione potrebbe causare infortuni alle persone. Prima di intervenire su qualsiasi apparecchiatura, occorre essere al corrente dei pericoli relativi ai circuiti elettrici e conoscere le procedure standard per la prevenzione di incidenti.
About this Guide Cisco ONS 15454 SDH Reference Manual, R5.
About this Guide Aviso INSTRUÇÕES IMPORTANTES DE SEGURANÇA Este símbolo de aviso significa perigo. Você se encontra em uma situação em que há risco de lesões corporais. Antes de trabalhar com qualquer equipamento, esteja ciente dos riscos que envolvem os circuitos elétricos e familiarize-se com as práticas padrão de prevenção de acidentes. Use o número da declaração fornecido ao final de cada aviso para localizar sua tradução nos avisos de segurança traduzidos que acompanham o dispositivo.
About this Guide Cisco ONS 15454 SDH Reference Manual, R5.
About this Guide Obtaining Optical Networking Information This section contains information that is specific to optical networking products. For information that pertains to all of Cisco, refer to the Obtaining Documentation and Submitting a Service Request section. Where to Find Safety and Warning Information For safety and warning information, refer to the Cisco Optical Transport Products Safety and Compliance Information document that accompanied the product.
C H A P T E R 1 Shelf and FMEC Hardware This chapter provides a description of Cisco ONS 15454 SDH shelf and backplane hardware. Card and cable descriptions are provided in Chapter 2, “Common Control Cards,” Chapter 3, “Electrical Cards,” Chapter 4, “Optical Cards,” and Chapter 14, “Ethernet Operation.” To install equipment, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: Note Caution • 1.1 Overview, page 1-1 • 1.2 Front Door, page 1-3 • 1.
Chapter 1 Shelf and FMEC Hardware 1.1 Overview documentation. If you are unsure about the requirements or specifications for a fuse and alarm panel, consult the user documentation for the related equipment. The front door of the ONS 15454 SDH allows access to the shelf assembly, fan-tray assembly, and cable-management area. The FMEC cover at the top of the shelf allows access to power connectors, external alarms and controls, timing input and output, and craft interface terminals.
Chapter 1 Shelf and FMEC Hardware 1.2 Front Door Figure 1-1 provides the dimensions of the ONS 15454 SDH. Figure 1-1 ONS 15454 SDH Dimensions Top View 535 mm (21.06 in.) total width 280 mm (11.02 in.) Side View 40 mm (1.57 in.) Front View 280 mm (11.02 in.) 535 mm (21.06 in.) total width 61213 616.5 mm (24.27 in.) 1.2 Front Door The Critical, Major, and Minor alarm LEDs visible through the front door indicate whether a critical, major, or minor alarm is present anywhere on the ONS 15454 SDH.
Chapter 1 Shelf and FMEC Hardware 1.2 Front Door Figure 1-2 The ONS 15454 SDH Front Door CISCO ONS 15454 Optical Network System Door lock Door button 33923 Viewholes for Critical, Major and Minor alarm LEDs Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 1 Shelf and FMEC Hardware 1.2 Front Door You can remove the front door of the ONS 15454 SDH to provide unrestricted access to the front of the shelf assembly (Figure 1-3). Removing the ONS 15454 SDH Front Door FAN 61237 Figure 1-3 FAIL CR IT MAJ MIN Translucent circles for LED viewing Door hinge Assembly hinge pin Assembly hinge Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 1 Shelf and FMEC Hardware 1.2 Front Door An erasable label is pasted on the inside of the front door (Figure 1-4). You can use the label to record slot assignments, port assignments, card types, node ID, rack ID, and serial number for the ONS 15454 SDH. Figure 1-4 Front-Door Erasable Label P/N 47-12460-01 The front door label also includes the Class I and Class 1M laser warning (Figure 1-5). Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 1 Shelf and FMEC Hardware 1.3 Front Mount Electrical Connection Laser Warning on the Front-Door Label 78099 Figure 1-5 1.3 Front Mount Electrical Connection The positive and negative power terminals are located on FMEC cards in the Electrical Facility Connection Assembly (EFCA). The ground connection is the grounding receptacle on the side panel of the shelf. The ONS 15454 SDH EFCA at the top of the shelf has 12 FMEC slots numbered sequentially from left to right (18 to 29).
Chapter 1 Shelf and FMEC Hardware 1.3 Front Mount Electrical Connection • FMEC Slot 20 supports an electrical card in Slot 3. • FMEC Slot 21 supports an electrical card in Slot 4. • FMEC Slot 22 supports an electrical card in Slot 5. • FMEC Slot 23 hosts the MIC-A/P alarm and power FMEC. • FMEC Slot 24 supports the MIC-C/T/P timing, craft, and power FMEC. • FMEC Slot 25 supports an electrical card in Slot 13. • FMEC Slot 26 supports an electrical card in Slot 14.
Chapter 1 Shelf and FMEC Hardware 1.4 E1-75/120 Conversion Panel Table 1-2 FMEC, Ports, Line Rates, and Connectors (continued) FMEC Ports Line Rate per Port Connector Type Connector Location FMEC E1-120PROB 3 to 42 2.048 Mbps Molex 96-pin LFH connector EFCA, Slots 26 to 29 FMEC-E3/DS3 12 34.368 Mbps 1.0/2.3 miniature coax connector EFCA 1.0/2.3 miniature coax connector EFCA 44.736 Mbps FMEC STM1E 1:1 12 (protected) or 155.
Chapter 1 Shelf and FMEC Hardware 1.5 Coaxial Cable Figure 1-6 Mounting the E1-75/120 Conversion Panel in a Rack 83912 Equipment rack 1.5 Coaxial Cable Caution Always use the supplied ESD wristband when working with a powered ONS 15454 SDH. Plug the wristband cable into the ESD jack located on the lower-right outside edge of the shelf assembly. All interfaces that are listed in Table 1-2 on page 1-8 with 1.0/2.
Chapter 1 Shelf and FMEC Hardware 1.7 Cable Routing and Management All E-1 interfaces that are listed in Table 1-2 on page 1-8 with DB-37 or with Molex 96-pin LFH connectors must be connected using a 120-ohm twisted-pair balanced cable. For the interfaces that use Molex 96-pin LFH connectors Cisco offers ready-made cables. 1.
Chapter 1 Shelf and FMEC Hardware 1.8 Fiber Management 1.8 Fiber Management The jumper routing fins are designed to route fiber jumpers out of both sides of the shelf. Slots 1 to 6 exit to the left, and Slots 12 to 17 exit to the right. Figure 1-8 shows fibers routed from cards in the left slots, down through the fins, then exiting out the fiber channel to the left. The maximum capacity of the fiber routing channel depends on the size of the fiber jumpers.
Chapter 1 Shelf and FMEC Hardware 1.9 Fan-Tray Assembly 1.9 Fan-Tray Assembly The fan-tray assembly is located at the bottom of the ONS 15454 SDH. After you install the fan-tray assembly, you only need to open the drawer if a fan fails, or if you need to replace or clean the fan-tray air filter. Do not operate an ONS 15454 SDH without a fan-tray air filter.
Chapter 1 Shelf and FMEC Hardware 1.9.1 Fan Speed 1.9.1 Fan Speed If one or more fans fail on the fan-tray assembly, replace the entire assembly. You cannot replace individual fans. The red Fan Fail LED on the front of the fan tray illuminates when one or more fans fail. For fan tray replacement instructions, refer to the Cisco ONS 15454 SDH Troubleshooting Guide. The red Fan Fail LED clears after you install a working fan-tray assembly. Fan speed is controlled by TCC2/TCC2P card temperature sensors.
Chapter 1 Shelf and FMEC Hardware 1.12 Cards and Slots 1.12 Cards and Slots ONS 15454 SDH cards have electrical plugs at the back that plug into electrical connectors on the shelf assembly backplane. When the ejectors are fully closed, the card plugs into the assembly backplane Figure 1-10 shows card installation. Installing Cards in the ONS 15454 SDH FAN 61239 Figure 1-10 FAIL CR IT MAJ MIN Ejector Guide rail 1.12.
Chapter 1 Shelf and FMEC Hardware 1.12.1 Card Slot Requirements Shelf assembly slots have symbols indicating the type of cards that you can install in them. Each ONS 15454 SDH card has a corresponding symbol. The symbol on the card must match the symbol on the slot. Table 1-4 shows the slot and card symbol definitions. Table 1-4 Symbol Color/Shape Slot and Card Symbols Definition Orange/Circle Slots 1 to 6 and 12 to 17. Only install ONS 15454 SDH cards with a circle symbol on the faceplate.
Chapter 1 Shelf and FMEC Hardware 1.12.1 Card Slot Requirements Table 1-5 Card Ports, Line Rates, and Connectors (continued) Card Ports Line Rate per Port Connector Types Connector Location E100T-G 12 100 Mbps RJ-45 Faceplate E1000-2-G 2 1 Gbps SC (GBIC) Faceplate G1000-4 4 1 Gbps SC (GBIC) Faceplate G1K-4 4 1 Gbps SC (GBIC) Faceplate ML100T-12 12 100 Mbps RJ-45 Faceplate ML1000-2 2 1 Gbps LC (SFP) Faceplate OC3 IR 4/STM1 SH 4 1310 155.
Chapter 1 Shelf and FMEC Hardware 1.12.2 Card Replacement 1.12.2 Card Replacement To replace an ONS 15454 SDH card with another card of the same type, you do not need to make any changes to the database; remove the old card and replace it with a new card. To replace a card with a card of a different type, physically remove the card and replace it with the new card, then delete the original card from CTC. For specifics, refer to the Cisco ONS 15454 SDH Procedure Guide.
Chapter 1 Shelf and FMEC Hardware 1.13 Software and Hardware Compatibility Table 1-6 ONS 15454 SDH Software Release/Hardware Compatibility—XC-VXL-2.5G Configurations (continued) Hardware 3.40.0x (3.4) 4.0.0x (4.0) 4.1.0x (4.1) 4.6.0x (4.6) 5.0.0x (5.
Chapter 1 Shelf and FMEC Hardware 1.13 Software and Hardware Compatibility Table 1-7 ONS 15454 SDH Software Release/Hardware Compatibility—XC10G and XC-VXL-10G Configurations (continued) 4.0.0x (4.0) 4.1.0x (4.1) Hardware 3.40.0x (3.4) 4.6.0x (4.6) 5.0.0x (5.
Chapter 1 Shelf and FMEC Hardware 1.13 Software and Hardware Compatibility If an upgrade is required for compatibility, go to the Cisco Technical Assistance Center (Cisco TAC) website at http://www.cisco.com/tac. Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 1 Shelf and FMEC Hardware 1.13 Software and Hardware Compatibility Cisco ONS 15454 SDH Reference Manual, R5.
C H A P T E R 2 Common Control Cards This chapter describes the Cisco ONS 15454 SDH common control card functions. It includes descriptions, hardware specifications, and block diagrams for each card. For installation and card turn-up procedures, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 2.1 Common Control Card Overview, page 2-1 • 2.2 TCC2 Card, page 2-4 • 2.3 TCC2P Card, page 2-7 • 2.4 XC10G Card, page 2-10 • 2.5 XC-VXL-10G Card, page 2-12 • 2.6 XC-VXL-2.
Chapter 2 Common Control Cards 2.1.2 Card Compatibility Table 2-1 Common Control Cards for the ONS 15454 SDH For Additional Information... Card Description TCC2 The Advanced Timing, Communications, and Control See the “2.2 TCC2 Card” section on page 2-4. (TCC2) card is the main processing center of the ONS 15454 SDH and provides system initialization, provisioning, alarm reporting, maintenance, and diagnostics. TCC2P The Advanced Timing, Communications, and Control See the “2.
Chapter 2 Common Control Cards 2.1.3 Cross-Connect Card Compatibility Table 2-2 Common-Control Card Software Release Compatibility (continued) Card R4.0 R4.1 R4.5 R4.6 R4.7 R5.0 XC10G Yes Yes — Yes Yes Yes XC-VXL-10G Yes Yes Yes Yes Yes Yes XC-VXL-2.5G Yes Yes Yes Yes Yes Yes AIC-I Yes Yes Yes Yes Yes Yes 2.1.3 Cross-Connect Card Compatibility The following tables list the compatible cross-connect cards for each Cisco ONS 15454 SDH common-control card.
Chapter 2 Common Control Cards 2.2 TCC2 Card Table 2-5 lists the cross-connect card compatibility for each optical card. Table 2-5 Optical Card Cross-Connect Compatibility Optical Card XC10G Card XC-VXL-2.
Chapter 2 Common Control Cards 2.2 TCC2 Card Note The LAN interfaces of the TCC2 card meet the standard Ethernet specifications by supporting a cable length of 100 m (328 ft.) at temperatures from 0 to 65 degrees Celsius (32 to 149 degrees Fahrenheit). The interfaces can operate with a cable length of 10 m (32.8 ft) maximum at temperatures from –40 to 0 degrees Celsius (–40 to 32 degrees Fahrenheit). Note The TCC2 card supporst both –48 VDC and –60 VDC input requirements.
Chapter 2 Common Control Cards 2.2.1 TCC2 Card Functionality 2.2.1 TCC2 Card Functionality The TCC2 card supports multichannel, high-level data link control (HDLC) processing for the DCC/GCC. Up to 84 DCCs can be routed over the TCC2 card and up to 84 section DCCs can be terminated at the TCC2 card (subject to the available optical digital communication channels). The TCC2 card selects and processes 84 DCCs to facilitate remote system management interfaces.
Chapter 2 Common Control Cards 2.2.3 Network-Level Indicators Table 2-7 TCC2 Card-Level Indicators Card-Level LEDs Definition Red FAIL LED The FAIL LED flashes during the boot and write process. Replace the card if the FAIL LED persists. ACT/STBY LED The ACT/STBY (Active/Standby) LED indicates the TCC2 card is active (green) or in standby (amber) mode. The ACT/STBY LED also provides the timing reference and shelf control.
Chapter 2 Common Control Cards 2.3.1 TCC2P Functionality Figure 2-2 shows the faceplate and block diagram for the TCC2P. Figure 2-2 TCC2P Faceplate and Block Diagram TCC2P FAIL RAM PWR A Flash B DCC Processor ACT/STBY Secure 10BaseT Modem CRIT Ethernet Switch MAJ MIN REM SYNC ACO Timing Controller RAM Flash Control Processor ACO 10BaseT Craft LAMP Framer/ LIU Message Router RS-232 Voltage Monitoring TDM Crossconnect 115483 TCP/IP TDM/SCC Mux B a c k p l a n e 2.3.
Chapter 2 Common Control Cards 2.3.2 TCC2P Card-Level Indicators The node database, IP address, and system software are stored in TCC2P nonvolatile memory, which allows quick recovery in the event of a power or card failure. The TCC2P card performs all system-timing functions for each ONS 15454. It monitors the recovered clocks from each traffic card and two BITS ports for frequency accuracy.
Chapter 2 Common Control Cards 2.3.3 Network-Level Indicators 2.3.3 Network-Level Indicators Table 2-10 describes the six network-level LEDs on the TCC2P faceplate. Table 2-10 TCC2P Network-Level Indicators System-Level LEDs Definition Red CRIT LED Indicates critical alarms in the network at the local terminal. Red MAJ LED Indicates major alarms in the network at the local terminal. Amber MIN LED Indicates minor alarms in the network at the local terminal.
Chapter 2 Common Control Cards 2.4 XC10G Card Figure 2-3 shows the XC10G card faceplate and block diagram. Figure 2-3 XC10G Card Faceplate and Block Diagram Line 1 XC10G Line 2 Line 3 Line 4 FAIL uP Interface ACT/STBY Span 1 Span 2 Cross-Connect Matrix Span 3 Span 4 Line 5 Line 6 Line 7 Line 8 Ref Clk A Flash Ref Clk B B a c k p l a n e RAM TCCA ASIC uP Interface Protect SCL SCL link 110948 Main SCL uP Figure 2-4 shows the XC10G card cross-connect matrix.
Chapter 2 Common Control Cards 2.4.1 XC10G Functionality 2.4.1 XC10G Functionality The XC10G card manages up to 192 bidirectional STM-1 cross-connects. The TCC2/TCC2P card assigns bandwidth to each slot on a per STM-1 basis. The XC10G card works with the TCC2/TCC2P card to maintain connections and set up cross-connects within the system. You can establish cross-connect and provisioning information through the CTC. Note Cisco does not recommend operating the ONS 15454 SDH with only one XC10G card.
Chapter 2 Common Control Cards 2.5 XC-VXL-10G Card Figure 2-5 shows the XC-VXL-10G faceplate and block diagram. Figure 2-5 XC-VXL-10G Faceplate and Block Diagram XCVXL Line 1 10G Line 2 Line 3 Line 4 FAIL uP Interface ACT/STBY Span 1 Span 2 Cross-Connect Matrix Span 3 Span 4 Line 5 Line 6 Line 7 Line 8 Ref Clk A Flash Ref Clk B B a c k p l a n e RAM TCCA ASIC uP Interface Protect SCL SCL link 110949 Main SCL uP Figure 2-6 shows the XC-VXL-10G cross-connect matrix.
Chapter 2 Common Control Cards 2.5.1 XC-VXL-10G Functionality 2.5.1 XC-VXL-10G Functionality The XC-VXL-10G card manages up to 192 bidirectional STM-1 cross-connects, 192 bidirectional E-3 or DS-3 cross-connects, or 1008 bidirectional E-1 cross-connects. The TCC2/TCC2P card assigns bandwidth to each slot on a per STM-1 basis. The XC-VXL-10G card works with the TCC2/TCC2P card to maintain connections and set up cross-connects within the node.
Chapter 2 Common Control Cards 2.6 XC-VXL-2.5G Card Figure 2-7 shows the XC-VXL-2.5G card faceplate and block diagram. Figure 2-7 XC-VXL-2.5G Faceplate and Block Diagram XCVXL Line 1 2.5G Line 2 Line 3 Line 4 FAIL uP Interface ACT/STBY Span 1 Span 2 Cross-Connect Matrix Span 3 Span 4 Line 5 Line 6 Line 7 Line 8 Ref Clk A Flash Ref Clk B B a c k p l a n e RAM TCCA ASIC uP Interface Protect SCL SCL link 110950 Main SCL uP Figure 2-8 shows the XC-VXL-2.5G cross-connect matrix.
Chapter 2 Common Control Cards 2.6.1 XC-VXL-2.5G Card Functionality 2.6.1 XC-VXL-2.5G Card Functionality The XC-VXL-2.5G card manages up to 192 bidirectional STM-1 cross-connects, 192 bidirectional E-3 or DS-3 cross-connects, or 1008 bidirectional E-1 cross-connects. The TCC2/TCC2P card assigns bandwidth to each slot on a per STM-1 basis. The XC-VXL-2.5G card works with the TCC2/TCC2P card to maintain connections and set up cross-connects within the node.
Chapter 2 Common Control Cards 2.7.1 AIC-I Card-Level Indicators Figure 2-9 shows the AIC-I card faceplate and a block diagram of the card. Figure 2-9 AIC-I Faceplate and Block Diagram AIC-1 FAIL Fail PWR A B AIC-I Act ACT UDC-A UDC-B ACC INPUT/OUTPUT DCC-A DCC-B Express orderwire ACC (DTMF) Ring Local orderwire 12/16 x IN (DTMF) UDC-A Ring 4x IN/OUT UDC-B Ringer DCC-A Power Monitoring DCC-B RING Input LOW LED x2 AIC-I FPGA Output EOW RING EEPROM 78828 SCL links 2.7.
Chapter 2 Common Control Cards 2.7.2 External Alarms and Controls Table 2-14 AIC-I Card-Level Indicators (continued) Card-Level LEDs Description Green/Red PWR B LED When green, indicates that a supply voltage within the specified range has been sensed on supply input B. It is red when the input voltage on supply input B is out of range. Amber INPUT LED When amber, indicates that there is an alarm condition on at least one of the alarm inputs.
Chapter 2 Common Control Cards 2.7.3 Orderwire • Virtual wire entities: You can provision any environmental alarm input to raise a signal on any virtual wire on external outputs 1 through 4 when the alarm input is an event. You can provision a signal on any virtual wire as a trigger for an external control output. You can also program the output alarm contacts (external controls) separately. In addition to provisionable triggers, you can manually force each external output contact to open or close.
Chapter 2 Common Control Cards 2.7.4 Power Monitoring Table 2-15 describes the orderwire pin assignments. Table 2-15 Orderwire Pin Assignments RJ-11 Pin Number Description 1 Four-wire receive ring 2 Four-wire transmit tip 3 Two-wire ring 4 Two-wire tip 5 Four-wire transmit ring 6 Four-wire receive tip When provisioning the orderwire subnetwork, make sure that an orderwire loop does not exist. Loops cause oscillation and an unusable orderwire channel.
Chapter 2 Common Control Cards 2.7.6 Data Communications Channel Table 2-16 UDC Pin Assignments (continued) RJ-11 Pin Number Description 3 RXN 4 RXP 5 TXP 6 For future use 2.7.6 Data Communications Channel The DCC features a dedicated data channel of 576 kbps (D4 to D12 bytes) between two nodes in an ONS 15454 SDH network. Each AIC-I card provides two DCCs, DCC-A and DCC-B, through separate RJ-45 connectors on the front of the AIC-I.
Chapter 2 Common Control Cards 2.7.6 Data Communications Channel Cisco ONS 15454 SDH Reference Manual, R5.
C H A P T E R 3 Electrical Cards This chapter describes the Cisco ONS 15454 SDH electrical card features and functions. It includes descriptions, hardware specifications, and block diagrams for each card. For installation and card turn-up procedures, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 3.1 Electrical Card Overview, page 3-1 • 3.2 E1-N-14 Card, page 3-4 • 3.3 E1-42 Card, page 3-6 • 3.4 E3-12 Card, page 3-8 • 3.5 DS3i-N-12 Card, page 3-10 • 3.
Chapter 3 Electrical Cards 3.1.1 Card Summary Note Each card is marked with a symbol that corresponds to a slot (or slots) on the ONS 15454 shelf assembly. The cards are then installed into slots displaying the same symbols. See the “1.12.1 Card Slot Requirements” section on page 1-15 for a list of slots and symbols. 3.1.1 Card Summary Table 3-1 shows available electrical cards for the ONS 15454 SDH. Table 3-1 Electrical Cards Card Description For Additional Information...
Chapter 3 Electrical Cards 3.1.1 Card Summary Table 3-1 Electrical Cards (continued) Card Description For Additional Information... FMEC E1-120PROA See the “3.11 FMEC Provides electrical connection into the system for 42 pairs of 120-ohm balanced E1-120PROA Card” section E-1 ports from the E1-42 card. It is for on page 3-21. 1:3 protection from the A side (left side of the shelf). It occupies four slots, Slots 18 to 21. It uses Molex 96-pin LFH connectors. FMEC E1-120PROB See the “3.
Chapter 3 Electrical Cards 3.1.2 Card Compatibility 3.1.2 Card Compatibility Table 3-2 lists the CTC software compatibility for each electrical card. See Table 2-4 on page 2-3 for a list of cross-connect cards that are compatible with each electrical card. Table 3-2 Electrical Card Software Release Compatibility Electrical Card R3.3 R3.4 R4.0 R4.1 R4.5 R4.6 R4.7 R5.
Chapter 3 Electrical Cards 3.2.1 E1-N-14 Card Functionality Figure 3-1 E1-N-14 Faceplate and Block Diagram E1-N 14 FAIL ACT/STBY SF Protection Relay Matrix 14 Line Interface Units AU-3 to 14 E1 Mapper AU-3 / STM-4 Mux/Demux FPGA BTC ASIC B a c k p l a n e DRAM FLASH 134371 uP 3.2.1 E1-N-14 Card Functionality Each E1-N-14 port features ITU-T G.703 compliant outputs and inputs supporting cable losses of up to 6 dB at 1024 kHz. The E1-N-14 card supports 1:N (N <= 4) protection.
Chapter 3 Electrical Cards 3.2.2 E1-N-14 Card-Level Indicators Note The lowest level cross-connect with the XC10G card is STM-1. Lower level signals, such as E-1, DS-3, or E-3, can be dropped. This might leave part of the bandwidth unused. The lowest level cross-connect with the XC-VXL-10G card and with the XC-VXL-2.5G card is VC-12 (2.048 Mbps). 3.2.2 E1-N-14 Card-Level Indicators Table 3-3 describes the three E1-N-14 card faceplate LEDs.
Chapter 3 Electrical Cards 3.3.1 E1-42 Card Functionality Figure 3-2 E1-42 Faceplate and Block Diagram E1-42 FAIL ACT/STBY SF Protection Relay Matrix 6 * 7 Line Interface Units AU-4 to 2 * 21 E1 Mapper AU-4 / STM-4 BTC ASIC B a c k p l a n e DRAM FLASH 134377 uP 3.3.1 E1-42 Card Functionality Each E1-42 port features ITU-T G.703 compliant outputs and inputs supporting cable losses of up to 6 dB at 1024 kHz. The E1-42 card supports 1:3 protection.
Chapter 3 Electrical Cards 3.3.2 E1-42 Card-Level Indicators 3.3.2 E1-42 Card-Level Indicators Table 3-4 describes the three LEDs on the E1-42 card faceplate. Table 3-4 E1-42 Card-Level Indicators Card-Level LEDs Description Red FAIL LED Indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the FAIL LED persists in flashing.
Chapter 3 Electrical Cards 3.4.1 E3-12 Card Functionality Figure 3-3 E3-12 Card Faceplate and Block Diagram FAIL ACT/STBY Protection Relay Matrix SF 12 Line Interface Units E3 ASIC BTC ASIC B a c k p l a n e 134378 E3 12 3.4.1 E3-12 Card Functionality You can install the E3-12 card in Slots 1 to 5 and 14 to 17 on the ONS 15454 SDH. Each E3-12 port features ITU-T G.703 compliant outputs supporting cable losses of up to 12 dB at 17184 kHz. The E3-12 card supports 1:1 protection.
Chapter 3 Electrical Cards 3.4.2 E3-12 Card-Level Indicators 3.4.2 E3-12 Card-Level Indicators Table 3-5 describes the three LEDs on the E3-12 card faceplate. Table 3-5 E3-12 Card-Level Indicators Card-Level LEDs Description Red FAIL LED Indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the FAIL LED persists in flashing.
Chapter 3 Electrical Cards 3.5.1 DS3i-N-12 Card Functionality Figure 3-4 DS3i-N-12 Faceplate and Block Diagram DS3I- N 12 main DS3-m1 protect DS3-p1 Line Interface Unit #1 FAIL ACT/STBY SF DS3 ASIC BERT FPGA main DS3-m12 protect DS3-p12 Line Interface Unit #1 OHP FPGA BTC ASIC B a c k p l a n e Processor SDRAM Flash 134379 uP bus 3.5.1 DS3i-N-12 Card Functionality The DS3i-N-12 can detect several different errored logic bits within a DS-3 frame.
Chapter 3 Electrical Cards 3.5.2 DS3i-N-12 Card-Level Indicators • C-bit parity monitoring • X-bit monitoring • M-bit monitoring • F-bit monitoring • Far-end block error (FEBE) monitoring • Far-end alarm and control (FEAC) status and loop code detection • Path trace byte support with TIM-P alarm generation You can install the DS3i-N-12 card in Slots 1 to 5 and 13 to 17. Each DS3i-N-12 port features DS-N-level outputs supporting distances up to 137 m (450 feet).
Chapter 3 Electrical Cards 3.6 STM1E-12 Card 3.6 STM1E-12 Card The 12-port ONS 15454 SDH STM1E-12 card provides 12 ITU-compliant, G.703 STM-1 ports per card. Ports 9 to 12 can each be either E-4 or STM-1. Each interface operates at 155.52 Mbps for STM-1 or 139.264 Mbps for E-4 over a 75-ohm coaxial cable (with the FMEC STM1E 1:1 card). In E-4 mode, framed or unframed signal operation is possible. The STM1E-12 card operates as a working or protect card in 1:1 protection schemes.
Chapter 3 Electrical Cards 3.6.2 STM1E-12 Card-Level Indicators Note When a protection switch moves traffic from the STM1E-12 working/active card to the STM1E-12 protect/standby card, ports on the now active/standby card cannot be taken out of service. Lost traffic can result if you take a port out of service, even if the STM1E-12 active/standby card no longer carries traffic. Note Use an external clock when doing service disruption time measurements on the STM1E-12. 3.6.
Chapter 3 Electrical Cards 3.8 FMEC-E1 Card FILLER Faceplate 33678 12931 61333 Figure 3-6 3.8 FMEC-E1 Card The ONS 15454 SDH FMEC-E1 card provides front mount electrical connection for 14 ITU-compliant, G.703 E-1 ports. With the FMEC-E1 card, each E1-N-14 port operates at 2.048 Mbps over a 75-ohm unbalanced coaxial 1.0/2.3 miniature coax connector. Figure 3-7 shows the FMEC-E1 card faceplate and block diagram. Caution This interface can only be connected to SELV circuits.
Chapter 3 Electrical Cards 3.
Chapter 3 Electrical Cards 3.9.1 FMEC-DS1/E1 Card Connector Pinout You can install the FMEC-DS1/E1 card in any EFCA slot from Slot 18 to 22 or Slot 25 to 29 on the ONS 15454 SDH. Each FMEC-DS1/E1 card interface features E1-level inputs and outputs supporting cable losses of up to 6 dB at 1024 kHz. 3.9.1 FMEC-DS1/E1 Card Connector Pinout Use Table 3-8 to make the connection from the E-1 37-pin DB connector for Ports 1 to 7 to the external balanced 120-ohm E-1 interfaces.
Chapter 3 Electrical Cards 3.10 FMEC E1-120NP Card Table 3-9 E-1 Interface Pinouts on Ports 8 to 14 (continued) Pin No. Signal Name Pin No. Signal Name 5 TX 13 N 24 RX 13 N 6 GND 25 RX 12 P 7 TX 12 P 26 RX 12 N 8 TX 12 N 27 GND 9 TX 11 P 28 RX 11 P 10 TX 11 N 29 RX 11 N 11 GND 30 RX 10 P 12 TX 10 P 31 RX 10 N 13 TX 10 N 32 GND 14 TX 9 P 33 RX 9 P 15 TX 9 N 34 RX 9 N 16 GND 35 RX 8 P 17 TX 8 P 36 RX 8 N 18 TX 8 N 37 GND 19 GND — — 3.
Chapter 3 Electrical Cards 3.10.1 FMEC E1-120NP Connector Pinout Figure 3-9 FMEC E1-120NP Faceplate and Block Diagram Port 1 to 21 Connector PORT 1-21 CLEI CODE Port 22 to 42 Connector B a c k p l a n e 2 * 21 Pairs of Transformers BARCODE Inventory Data (EEPROM) PORT 22-42 134383 FMEC E1-120NP You can install the FMEC E1-120NP card in any EFCA slot from Slot 18 to 22 or Slot 25 to 29 on the ONS 15454 SDH.
Chapter 3 Electrical Cards 3.10.1 FMEC E1-120NP Connector Pinout Table 3-10 E-1 Interface Pinouts on Ports 1 to 21 (continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No.
Chapter 3 Electrical Cards 3.11 FMEC E1-120PROA Card Table 3-11 E-1 Interface Pinouts on Ports 22 to 42 (continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name 21 TX 22 N 45 RX 22 N 69 NC 93 NC 22 TX 22 P 46 RX 22 P 70 NC 94 NC 23 NC 47 NC 71 NC 95 NC 24 NC 48 NC 72 NC 96 NC 3.11 FMEC E1-120PROA Card The ONS 15454 SDH FMEC E1-120PROA card provides front mount electrical connection for 126 ITU compliant, G.703 E-1 ports.
Chapter 3 Electrical Cards 3.11.1 FMEC E1-120PROA Connector Pinout Table 3-12 E-1 Interface Pinouts on Ports 1 to 21 Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No.
Chapter 3 Electrical Cards 3.12 FMEC E1-120PROB Card Table 3-13 E-1 Interface Pinouts on Ports 22 to 42 (continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No.
Chapter 3 Electrical Cards 3.12.1 FMEC E1-120PROB Connector Pinout Figure 3-11 FMEC E1-120PROB Faceplate and Block Diagram PORT 1-21 PORT 1-21 PORT 1-21 6 Interface Connectors CLEI CODE Protect Switch Relay Matrix 4 x 42 Pairs of Transformers BARCODE Inventory Data (EEPROM) PORT 22-42 PORT 22-42 B a c k p l a n e PORT 22-42 134373 FMEC E1-120PROB You can install the FMEC E1-120PROB card in EFCA Slots 26 to 29 on the ONS 15454 SDH.
Chapter 3 Electrical Cards 3.12.1 FMEC E1-120PROB Connector Pinout Table 3-14 E-1 Interface Pinouts on Ports 1 to 21 (continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No.
Chapter 3 Electrical Cards 3.13 E1-75/120 Impedance Conversion Panel Table 3-15 E-1 Interface Pinouts on Ports 22 to 42 (continued) Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name Pin No. Signal Name 21 TX 22 N 45 RX 22 N 69 NC 93 NC 22 TX 22 P 46 RX 22 P 70 NC 94 NC 23 NC 47 NC 71 NC 95 NC 24 NC 48 NC 72 NC 96 NC 3.
Chapter 3 Electrical Cards 3.13 E1-75/120 Impedance Conversion Panel Figure 3-13 shows the E1-75/120 with optional rackmount brackets installed. Figure 3-13 E1-75/120 with Optional Rackmount Brackets ETSI rackmount bracket 83636 19 to 23 in. rackmount bracket Figure 3-14 shows a block diagram of the impedance conversion panel. Figure 3-14 E1-75/120 Impedance Conversion Panel Block Diagram 42 Channels Transformer 1.26:1 75-Ohm Unsymmetrical Signals Transformer 1.
Chapter 3 Electrical Cards 3.13.1 E1-75/120 Impedance Conversion Panel Functionality 3.13.1 E1-75/120 Impedance Conversion Panel Functionality You can install the E1-75/120 conversion panel in the rack containing the ONS 15454 SDH shelf or in a nearby rack. If you install the E1-75/120 conversion panel in a place where a longer cable is required, make sure that the total cable loss of the balanced 120-ohm cable and the unbalanced 75-ohm cable does not exceed the maximum allowed value.
Chapter 3 Electrical Cards 3.15 FMEC STM1E 1:1 Card – Up to 24 m (79 ft) RG179 3.15 FMEC STM1E 1:1 Card The ONS 15454 SDH FMEC STM1E 1:1 card provides front mount electrical connection for 2 x 12 ITU-compliant, G.703 STM1E ports. Ports 9 to 12 can be switched to E-4 instead of STM-1 (via CTC, on the STM1E-12 card). With the FMEC STM1E 1:1 card, each interface of an STM1E-12 card operates at 155.52 Mbps for STM-1 or 139.264 Mbps for E-4 over a 75-ohm unbalanced coaxial 1.0/2.3 miniature coax connector.
Chapter 3 Electrical Cards 3.17 MIC-A/P FMEC FMEC-BLANK Faceplate 61318 Figure 3-17 3.17 MIC-A/P FMEC The MIC-A/P FMEC provides connection for the BATTERY B input, one of the two possible redundant power supply inputs. It also provides connection for eight alarm outputs (coming from the TCC2/TCC2P card), sixteen alarm inputs, and four configurable alarm inputs/outputs. Its position is in Slot 23 in the center of the subrack EFCA area. Figure 3-18 shows the MIC-A/P faceplate and block diagram.
Chapter 3 Electrical Cards 3.17.1 MIC-A/P Connector Pinouts Note For proper system operation, both the MIC-A/P and the MIC-C/T/P FMECs must be installed in the ONS 15454 SDH shelf. Note The MIC-A/P card controls whether FMEC cards on its side of the shelf appear in the CTC graphical user interface (GUI). For example, if the MIC-A/P is removed from the shelf, FMECS to the left of the card may disappear in CTC.
Chapter 3 Electrical Cards 3.17.1 MIC-A/P Connector Pinouts Table 3-16 Alarm Interface Pinouts on the MIC-A/P DB-62 Connector (continued) Pin No.
Chapter 3 Electrical Cards 3.18 MIC-C/T/P FMEC Table 3-16 Alarm Interface Pinouts on the MIC-A/P DB-62 Connector (continued) Pin No. Signal Name Signal Description Color 59 VISALM2 N Normally open Critical visual alarm Black/blue 60 VISALM2 P Normally open Critical visual alarm Blue/black 61 VISALM3 N Normally open Remote visual alarm Black/orange 62 VISALM3 P Normally open Remote visual alarm Orange/black 3.
Chapter 3 Electrical Cards 3.18.1 MIC-C/T/P Port-Level Indicators 3.18.1 MIC-C/T/P Port-Level Indicators The MIC-C/T/P FMEC has one pair of LEDs located on the RJ-45 LAN connector. The green LED is on when a link is present, and the amber LED is on when data is being transferred. Cisco ONS 15454 SDH Reference Manual, R5.
C H A P T E R 4 Optical Cards This chapter describes the Cisco ONS 15454 SDH optical, transponder, and muxponder card features and functions. It includes descriptions, hardware specifications, and block diagrams for each card. For installation and card turn-up procedures, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 4.1 Optical Card Overview, page 4-1 • 4.2 OC3 IR 4/STM1 SH 1310 Card, page 4-4 • 4.3 OC3 IR/STM1 SH 1310-8 Card, page 4-7 • 4.
Chapter 4 Optical Cards 4.1.1 Card Summary 4.1.1 Card Summary Table 4-1 lists the ONS 15454 SDH optical cards. Table 4-1 Optical Cards for the ONS 15454 SDH Card Description OC3 IR 4/STM1 SH 1310 The OC3 IR 4/STM1 SH 1310 card provides four See the “4.2 OC3 IR intermediate- or short-range STM-1 ports and operates 4/STM1 SH 1310 Card” at 1310 nm. It operates in Slots 1 to 6 and 12 to 17. section on page 4-4. OC3 IR/STM1 SH 1310-8 The OC3IR/STM1SH 1310-8 card provides eight See the “4.
Chapter 4 Optical Cards 4.1.2 Card Compatibility Table 4-1 Note Optical Cards for the ONS 15454 SDH (continued) Card Description For Additional Information... OC192 LR/STM64 LH 1550 The OC192 LR/STM64 LH 1550 card provides one long-range STM-64 port at 1550 nm and operates in Slots 5, 6, 12, or 13 with the XC10G card. See the “4.13 OC192 LR/STM64 LH 1550 Card” section on page 4-35. OC192 LR/STM64 LH ITU 15xx.xx The OC192 LR/STM64 LH ITU 15xx.xx card provides See the “4.
Chapter 4 Optical Cards 4.2 OC3 IR 4/STM1 SH 1310 Card Table 4-2 Optical Card Software Release Compatibility (continued) Optical Card R2.2.1 R2.2.2 R3.0.1 R3.1 R3.2 R3.3 R3.4 R4.0 R4.1 R4.5 R4.6 R4.7 R5.
Chapter 4 Optical Cards 4.2 OC3 IR 4/STM1 SH 1310 Card Figure 4-1 shows the OC3 IR 4/STM1 SH 1310 faceplate. Figure 4-1 OC3 IR 4/STM1 SH 1310 Faceplate OC3IR STM1SH 1310 FAIL ACT SF Tx 1 Rx Tx 2 Rx Tx 3 Rx Tx 4 33678 12931 63107 Rx Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 4 Optical Cards 4.2.1 OC3 IR 4/STM1 SH 1310 Functionality Figure 4-2 shows a block diagram of the four-port OC-3 card. Figure 4-2 STM-1 STM-1 STM-1 STM-1 OC3 IR 4/STM1 SH 1310 Block Diagram STM-4 Optical Transceiver STM-1 termination/ framing Optical Transceiver STM-1 termination/ framing Optical Transceiver STM-1 termination/ framing Optical Transceiver STM-1 termination/ framing Flash STM-4/ STM-1 Mux/Demux BTC ASIC B a c k p l a n e RAM uP bus 63118 uP 4.2.
Chapter 4 Optical Cards 4.2.2 OC3 IR 4/STM1 SH 1310 Card-Level Indicators 4.2.2 OC3 IR 4/STM1 SH 1310 Card-Level Indicators Table 4-3 describes the three card-level LED indicators on the OC3 IR 4/STM1 SH 1310 card. Table 4-3 OC3 IR 4/STM1 SH 1310 Card-Level Indicators Card-Level LED Description Red FAIL LED The red FAIL LED indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the red FAIL LED persists.
Chapter 4 Optical Cards 4.3 OC3 IR/STM1 SH 1310-8 Card Figure 4-3 OC3 IR/STM1 SH 1310-8 Faceplate OC3IR STM1SH 1310-8 FAIL ACT 33678 12931 83642 SF Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 4 Optical Cards 4.3 OC3 IR/STM1 SH 1310-8 Card Figure 4-4 shows a block diagram of the OC3 IR/STM1 SH 1310-8 card.
Chapter 4 Optical Cards 4.3.1 OC3 IR/STM1 SH 1310-8 Card-Level Indicators 4.3.1 OC3 IR/STM1 SH 1310-8 Card-Level Indicators Table 4-4 describes the three card-level LED indicators for the OC3IR/STM1 SH 1310-8 card. Table 4-4 OC3IR/STM1 SH 1310-8 Card-Level Indicators Card-Level LED Description Red FAIL LED The red FAIL LED indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the red FAIL LED persists.
Chapter 4 Optical Cards 4.4 OC12 IR/STM4 SH 1310 Card 4.4 OC12 IR/STM4 SH 1310 Card The OC12 IR/STM4 SH 1310 card provides one intermediate or short range SDH STM-4 port compliant with ITU-T G.707 and ITU-T G.957. The port operates at 622.08 Mbps over a single-mode fiber span. The card supports VC-4 and nonconcatenated or concatenated payloads at STM-1 and STM-4 signal levels. Figure 4-5 shows the OC12 IR/STM4 SH 1310 faceplate and a block diagram of the card.
Chapter 4 Optical Cards 4.4.1 OC12 IR/STM4 SH 1310 Card-Level Indicators The OC12 IR/STM4 SH 1310 card interface features a 1310-nm laser and contains a transmit and receive connector (labeled) on the card faceplate. The OC12 IR/STM4 SH 1310 card uses SC optical connections and supports 1+1 unidirectional and bidirectional protection. The OC12 IR/STM4 SH 1310 detects LOS, LOF, LOP, MS-AIS, and MS-FERF conditions.
Chapter 4 Optical Cards 4.5 OC12 LR/STM4 LH 1310 Card Figure 4-6 OC12 LR/STM4 LH 1310 Faceplate OC12LR STM4LH 1310 FAIL ACT SF Tx 1 33678 12931 61223 Rx Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 4 Optical Cards 4.5.1 OC12 LR/STM4 LH 1310 Card-Level Indicators Figure 4-7 shows a block diagram of the card. Figure 4-7 OC12 LR/STM4 LH 1310 Block Diagram STM-4 STM-4 Mux/ Demux Optical Transceiver Flash STM-4 Cross Connect Matrix RAM uP bus B a c k Main SCI p l a Protect SCI n e 61225 uP You can install the OC12 LR/STM4 LH 1310 card in Slots 1 to 6 and 12 to 17 and provision the card as part of an MSP-SPRing or SNCP ring.
Chapter 4 Optical Cards 4.5.2 OC12 LR/STM4 LH 1310 Port-Level Indicators Table 4-6 OC12 LR/STM4 LH 1310 Card-Level Indicators (continued) Card-Level LED Description Green/Amber ACT LED The green ACT LED indicates that the card is operational and is carrying traffic or is traffic-ready. The amber ACT LED indicates that the card is in standby mode or is part of an active ring switch (BLSR).
Chapter 4 Optical Cards 4.6.1 OC12 LR/STM4 LH 1550 Card Functionality Figure 4-8 shows the OC12 LR/STM4 LH 1550 faceplate and a block diagram of the card. Figure 4-8 OC12 LR/STM4 LH 1550 Faceplate and Block Diagram OC12LR STM4LH 1550 FAIL ACT SF STS-12 Tx 1 OC12/STM-4 Rx Mux/ Demux Optical Transceiver Flash B a c k Main SCI p l a Protect SCI n e STS-12 BTC ASIC RAM uP bus 110871 uP 4.6.
Chapter 4 Optical Cards 4.6.2 OC12 LR/STM4 LH 1550 Card-Level Indicators The OC12 LR/STM4 LH 1550 card detects LOS, LOF, LOP, MS-AIS, and MS-FERF conditions. Refer to the Cisco ONS 15454 SDH Troubleshooting Guide for a description of these conditions. The card also counts section and line BIP errors. To enable an MSP-SPRing, the OC12 LR/STM4 LH 1550 extracts the K1 and K2 bytes from the SDH overhead and processes them to switch accordingly.
Chapter 4 Optical Cards 4.7 OC12 IR/STM4 SH 1310-4 Card Figure 4-9 OC12 IR/STM4 SH 1310-4 Faceplate OC12IR STM4SH 1310-4 FAIL ACT SF Tx 1 Rx Tx 2 Rx Tx 3 Rx Tx 4 33678 12931 78786 Rx Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 4 Optical Cards 4.7.1 OC12 IR/STM4 SH 1310-4 Card Functionality Figure 4-10 shows a block diagram of the card. Figure 4-10 STM-4 STM-4 STM-4 STM-4 OC12 IR/STM4 SH 1310-4 Block Diagram STM-4 Optical Transceiver STM-4 termination/ framing Optical Transceiver STM-4 termination/ framing Optical Transceiver STM-4 termination/ framing Optical Transceiver STM-4 termination/ framing Flash BTC ASIC B a c k p l a n e RAM uP bus 78787 uP 4.7.
Chapter 4 Optical Cards 4.7.2 OC12 IR/STM4 SH 1310-4 Card-Level Indicators Note If you ever expect to upgrade an OC-12/STM-4 ring to a higher bit rate, you should not put an OC12 IR/STM4 SH 1310-4 card in that ring. The four-port card is not upgradable to a single-port card. The reason is that four different spans, possibly going to four different nodes, cannot be merged to a single span. 4.7.
Chapter 4 Optical Cards 4.8 OC48 IR/STM16 SH AS 1310 Card Figure 4-11 OC48 IR/STM16 SH AS 1310 Faceplate OC48IR STM16SH AS 1310 FAIL ACT SF TX 1 33678 12931 63109 RX Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 4 Optical Cards 4.8.1 OC48 IR/STM16 SH AS 1310 Card Functionality Figure 4-12 shows a block diagram of the card. Figure 4-12 OC48 IR/STM16 SH AS 1310 Block Diagram STM-16 Optical Transceiver Flash Mux/ Demux BTC ASIC RAM B a c k Main SCI p l a Protect SCI n e STM-16 uP bus 63119 uP 4.8.1 OC48 IR/STM16 SH AS 1310 Card Functionality You can install the OC48 IR/STM16 SH AS 1310 card in Slots 1 to 6 and 12 to 17. You can provision the card as part of a MS-SPRing or SNCP.
Chapter 4 Optical Cards 4.8.3 OC48 IR/STM16 SH AS 1310 Port-Level Indicators Table 4-9 OC48 IR/STM16 SH AS 1310 Card-Level Indicators (continued) Card-Level LED Description Green/Amber ACT LED The green ACT LED indicates that the card is carrying traffic or is traffic-ready. The amber ACT LED indicates that the card is in standby mode or is part of an active ring switch (BLSR).
Chapter 4 Optical Cards 4.9 OC48 LR/STM16 LH AS 1550 Card Figure 4-13 OC48 LR/STM16 LH AS 1550 Faceplate OC48LR STM16LH AS 1550 FAIL ACT SF TX 1 33678 12931 63108 RX Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 4 Optical Cards 4.9.1 OC48 LR/STM16 LH AS 1550 Card Functionality Figure 4-14 shows a block diagram of the card. Figure 4-14 OC48 LR/STM16 LH AS 1550 Block Diagram STM-16 Optical Transceiver Flash Mux/ Demux B a c k Main SCI p l a Protect SCI n e STM-16 BTC ASIC RAM uP bus 63119 uP 4.9.1 OC48 LR/STM16 LH AS 1550 Card Functionality You can install OC48 LR/STM16 LH AS 1550 cards in Slots 1 to 6 or 12 to 17. You can provision this card as part of a MS-SPRing or SNCP.
Chapter 4 Optical Cards 4.9.3 OC48 LR/STM16 LH AS 1550 Port-Level Indicators Table 4-10 OC48 LR/STM16 LH AS 1550 Card-Level Indicators (continued) Card-Level LED Description Green/Amber ACT LED The green ACT LED indicates that the card is carrying traffic or is traffic-ready. The amber ACT LED indicates that the card is in standby mode or is part of an active ring switch (BLSR).
Chapter 4 Optical Cards 4.10 OC48 ELR/STM16 EH 100 GHz Cards Figure 4-15 OC48 ELR/STM16 EH 100 GHz Faceplate OC48ELR STM16EH 15XX.XX FAIL ACT/STBY SF TX 1 63106 RX Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 4 Optical Cards 4.10.1 OC48 ELR/STM16 EH 100 GHz Card Functionality Figure 4-16 shows a block diagram of the card. Figure 4-16 OC48 ELR/STM16 EH 100 GHz Block Diagram STM-16 Optical Transceiver Flash Mux/ Demux BTC ASIC RAM B a c k Main SCI p l a Protect SCI n e STM-16 uP bus 63119 uP 4.10.1 OC48 ELR/STM16 EH 100 GHz Card Functionality You can install the OC48 ELR/STM16 EH 100 GHz cards in Slot 5, 6, 12, or 13. You can provision this card as part of a MS-SPRing or SNCP.
Chapter 4 Optical Cards 4.10.2 OC48 ELR/STM16 EH 100 GHz Card-Level Indicators The OC48 ELR/STM16 EH 100 GHz port features a 1550-nm range laser and contains a transmit and receive connector (labeled) on the card faceplate. The card uses SC connectors and supports 1+1 unidirectional and bidirectional protection switching. The OC48 ELR/STM16 EH 100 GHz cards detect LOS, LOF, LOP, MS-AIS, and MS-FERF conditions. Refer to the Cisco ONS 15454 SDH Troubleshooting Guide for a description of these conditions.
Chapter 4 Optical Cards 4.11 OC192 SR/STM64 IO 1310 Card Figure 4-17 OC192 SR/STM64 IO 1310 Faceplate OC192SR STM64IO 1310 FAIL ACT SF Tx 1 33678 12931 83644 Rx Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 4 Optical Cards 4.11.1 OC192 SR/STM64 IO 1310 Card Functionality Figure 4-18 shows a block diagram of the card. Figure 4-18 OC192 SR/STM64 IO 1310 Block Diagram STM-64/ OC-192 STM-64 / OC192 Optical transceiver Demux CDR Demux SCL BTC ASIC STM-64 / OC192 Optical transceiver Mux CK Mpy ADC x 8 SRAM Mux Flash STM-64/ OC-192 SCL B a c k p l a n e Processor 4.11.1 OC192 SR/STM64 IO 1310 Card Functionality You can install OC192 SR/STM64 IO 1310 cards in Slot 5, 6, 12, or 13.
Chapter 4 Optical Cards 4.11.3 OC192 SR/STM64 IO 1310 Port-Level Indicators Table 4-12 OC192 SR/STM64 IO 1310 Card-Level Indicators Card-Level LED Description Red FAIL LED The red FAIL LED indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the red FAIL LED persists. ACT/STBY LED If the ACT/STBY LED is green, the card is operational and ready to carry traffic.
Chapter 4 Optical Cards 4.12 OC192 IR/STM64 SH 1550 Card Figure 4-19 shows the OC192 IR/STM64 SH 1550 faceplate. Figure 4-19 OC192 IR/STM64 SH 1550 Faceplate OC192IR STM64SH 1550 FAIL ACT SF Tx 1 33678 12931 83645 Rx Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 4 Optical Cards 4.12.1 OC192 IR/STM64 SH 1550 Card Functionality Figure 4-20 shows a block diagram of the card. Figure 4-20 OC192 IR/STM64 SH 1550 Block Diagram STM-64/ OC-192 STM-64 / OC192 Optical transceiver Demux CDR Demux SCL BTC ASIC STM-64 / OC192 Optical transceiver Mux CK Mpy ADC x 8 SRAM Mux Flash STM-64/ OC-192 SCL B a c k p l a n e Processor 4.12.1 OC192 IR/STM64 SH 1550 Card Functionality You can install OC192 IR/STM64 SH 1550 cards in Slot 5, 6, 12, or 13.
Chapter 4 Optical Cards 4.12.2 OC192 IR/STM64 SH 1550 Card-Level Indicators 4.12.2 OC192 IR/STM64 SH 1550 Card-Level Indicators Table 4-13 describes the three card-level LED indicators on the OC192 IR/STM64 SH 1550 card. Table 4-13 OC192 IR/STM64 SH 1550 Card-Level Indicators Card-Level LED Description Red FAIL LED The red FAIL LED indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process. Replace the card if the red FAIL LED persists.
Chapter 4 Optical Cards 4.13 OC192 LR/STM64 LH 1550 Card Figure 4-21 OC192 LR/STM64 LH 1550 Faceplate and Block Diagram 1550 FAIL ACT/STBY SF OC-192/STM-64 STS Optical transceiver Demux CDR Mux SCL BTC ASIC TX 1 OC-192/STM-64 RX Optical transceiver Mux CK Mpy STS Mux SCL RX ! B a c k p l a n e MAX INPUT POWER LEVEL -7 dBm SRAM Flash Processor 115222 ADC x 8 Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 4 Optical Cards 4.13.1 OC192 LR/STM64 LH 1550 Card Functionality Figure 4-22 Enlarged Section of the OC192 LR/STM64 LH 1550 Faceplate 1550 FAIL ACT/STBY SF RX ! MAX INPUT POWER LEVEL -7 dBm TX 1 RX RX ! DATED JULY 26, 2001 LASER NOTICE No.50, AND 1040.11 EXCEPT FOR DEVIATIONS PURSUANT TO 115226 DATED JULY 26, 2001 LASER NOTICE No.50, AND 1040.11 EXCEPT FOR DEVIATIONS PURSUANT TO COMPLIES WITH 21 CFR 1040.10 COMPLIES WITH 21 CFR 1040.10 MAX INPUT POWER LEVEL -7 dBm 4.13.
Chapter 4 Optical Cards 4.13.2 OC192 LR/STM64 LH 1550 Card-Level Indicators The OC192 LR/STM64 LH 1550 card detects SF, LOS, or LOF conditions on the optical facility. Refer to the Cisco ONS 15454 SDH Troubleshooting Guide for a description of these conditions. The card also counts section and line BIP errors from B1 and B2 byte registers in the section and line overhead. Caution You must use a 20-dB fiber attenuator (19 to 24 dB) when working with the OC192 LR/STM64 LH 1550 card in a loopback.
Chapter 4 Optical Cards 4.14 OC192 LR/STM64 LH ITU 15xx.xx Card 4.14 OC192 LR/STM64 LH ITU 15xx.xx Card Sixteen distinct STM-64 ITU 100 GHz DWDM cards comprise the ONS 15454 SDH DWDM channel plan. The OC192 LR/STM64 LH ITU 15xx.xx card provides one long-range SDH STM-64 port per card, compliant with ITU-T G.707 and G.957, and Telcordia GR-253-CORE (except minimum and maximum transmit power, and minimum receive power). The port operates at 9.
Chapter 4 Optical Cards 4.14.1 OC192 LR/STM64 LH ITU 15xx.xx Card Functionality Figure 4-24 OC192 LR/STM64 LH ITU 15xx.xx Block Diagram STM-64/ OC-192 STM-64 / OC192 Optical transceiver Demux CDR Demux SCL BTC ASIC STM-64 / OC192 Optical transceiver Mux CK Mpy SRAM Flash SCL B a c k p l a n e Processor 63121 ADC x 8 Mux STM-64/ OC-192 4.14.1 OC192 LR/STM64 LH ITU 15xx.xx Card Functionality You can install OC192 LR/STM64 LH ITU 15xx.xx cards in Slot 5, 6, 12, or 13.
Chapter 4 Optical Cards 4.14.2 OC192 LR/STM64 LH ITU 15xx.xx Card-Level Indicators 4.14.2 OC192 LR/STM64 LH ITU 15xx.xx Card-Level Indicators Table 4-15 describes the three card-level LED indicators on the OC192 LR/STM64 LH ITU 15xx.xx card. Table 4-15 OC192 LR/STM64 LH ITU 15xx.xx Card-Level Indicators Card-Level LED Description Red FAIL LED The red FAIL LED indicates that the card’s processor is not ready. The FAIL LED is on during reset and flashes during the boot process.
Chapter 4 Optical Cards 4.14.3 OC192 LR/STM64 LH ITU 15xx.xx Port-Level Indicators Cisco ONS 15454 SDH Reference Manual, R5.
C H A P T E R 5 Ethernet Cards Note The terms “Unidirectional Path Switched Ring” and “UPSR” may appear in Cisco literature. These terms do not refer to using Cisco ONS 15xxx products in a unidirectional path switched ring configuration. Rather, these terms, as well as “Path Protected Mesh Network” and “PPMN,” refer generally to Cisco’s path protection feature, which may be used in any topological network configuration.
Chapter 5 Ethernet Cards 5.1.1 Cards Summary 5.1.1 Cards Summary Table 5-1 lists the Cisco ONS 15454 SDH Ethernet cards. Table 5-1 Ethernet Cards for the ONS 15454 SDH Card Port Description E100T-G The E100T-G card provides 12 switched, autosensing, See the “5.2 E100T-G Card” 10/100BaseT Ethernet ports. section on page 5-2. E1000-2-G The E1000-2-G card provides two IEEE-compliant, 1000-Mbps ports. Gigabit Interface Converters (GBICs) are separate. See the “5.3 E1000-2-G Card” section on page 5-4.
Chapter 5 Ethernet Cards 5.2 E100T-G Card The ports autoconfigure to operate at either half or full duplex and determine whether to enable or disable flow control. You can also configure Ethernet ports manually. Figure 5-1 shows the faceplate and a block diagram of the card.
Chapter 5 Ethernet Cards 5.2.1 E100T-G Slot Compatibility 5.2.1 E100T-G Slot Compatibility You can install the E100T-G card in Slots 1 to 6 and 12 to 17. Multiple E-Series Ethernet cards installed in an ONS 15454 SDH can act independently or as a single Ethernet switch. You can create logical SDH ports by provisioning a number of SDH channels to the packet switch entity within the ONS 15454 SDH. Logical ports can be created with a bandwidth granularity of VC-4. 5.2.
Chapter 5 Ethernet Cards 5.3 E1000-2-G Card The E1000-2-G card uses GBIC modular receptacles for the optical interfaces. For details, see the “5.8 GBICs and SFPs” section on page 5-14. Figure 5-2 shows the card faceplate and a block diagram of the card.
Chapter 5 Ethernet Cards 5.3.1 E1000-2-G Compatibility Each E1000-2-G card supports standards-based, Layer 2 Ethernet switching between its Ethernet interfaces and SDH interfaces on the ONS 15454 SDH. The IEEE 802.1Q VLAN tag logically isolates traffic (typically subscribers). Multiple E-Series Ethernet cards installed in an ONS 15454 SDH can act together as a single switching entity or as independent single switches supporting a variety of SDH port configurations.
Chapter 5 Ethernet Cards 5.4 G1000-4 Card 5.4 G1000-4 Card The ONS 15454 SDH uses G1000-4 cards for Gigabit Ethernet (1000 Mbps). The G1000-4 card provides four ports of IEEE-compliant, 1000-Mbps interfaces. Each port supports full-duplex operation for a maximum bandwidth of STM-16 on each card. The G1000-4 card uses GBIC modular receptacles for the optical interfaces. For details, see the “5.8 GBICs and SFPs” section on page 5-14. Figure 5-3 shows the card faceplate and the block diagram of the card.
Chapter 5 Ethernet Cards 5.4.1 G1000-4 Card-Level Indicators 5.4.1 G1000-4 Card-Level Indicators The G1000-4 card faceplate has two card-level LED indicators (Table 5-7). Table 5-7 G1000-4 Card-Level Indicators Card-Level LEDs Description FAIL LED (red) The red FAIL LED indicates that the card’s processor is not ready or that a catastrophic software failure occurred on the G1000-4 card. As part of the boot sequence, the FAIL LED turns on; it turns off if the software is deemed operational.
Chapter 5 Ethernet Cards 5.5.1 G1K-4 Compatibility Figure 5-4 shows the card faceplate and the block diagram of the card.
Chapter 5 Ethernet Cards 5.5.2 G1K-4 Card-Level Indicators 5.5.2 G1K-4 Card-Level Indicators The G1K-4 card faceplate has two card-level LED indicators, described in Table 5-9. Table 5-9 G1K-4 Card-Level Indicators Card-Level LEDs Description FAIL LED (red) The red FAIL LED indicates that the card’s processor is not ready or that a catastrophic software failure occurred on the G1K-4 card.
Chapter 5 Ethernet Cards 5.6.1 ML100T-12 Card-Level Indicators Figure 5-5 ML100T-12 Faceplate ML100T 12 ACT FAIL 0 1 2 3 4 5 6 7 8 9 10 83647 11 ML-Series cards feature two SDH virtual ports with a maximum combined bandwidth of VC4-16c. Each port carries an STM circuit with a size of VC3, VC4, VC4-2c, VC4-3c, VC4-4c, and VC4-8c.
Chapter 5 Ethernet Cards 5.6.2 ML100T-12 Port-Level Indicators Table 5-11 ML100T-12 Card-Level Indicators Card-Level LEDs Description Red SF LED The red SF LED indicates that the card’s processor is not ready or that a catastrophic software failure occurred on the ML100T-12 card. As part of the boot sequence, the FAIL LED is illuminated until the software deems the card operational. Green ACT LED A green ACT LED provides the operational status of the ML100T-12.
Chapter 5 Ethernet Cards 5.7.1 ML1000-2 Card-Level Indicators Figure 5-6 shows the ML1000-2 card faceplate. Figure 5-6 ML1000-2 Faceplate ML1000 2 FAIL ACT CONSOLE TX 1 RX LINK ACT TX 2 RX LINK 83648 ACT ML-Series cards feature two SDH virtual ports with a maximum combined bandwidth of VC4-16c. Each port carries an STM circuit with a size of VC3, VC4, VC4-2c, VC4-3c, VC4-4c, and VC4-8c.
Chapter 5 Ethernet Cards 5.7.2 ML1000-2 Port-Level Indicators Table 5-13 ML1000-2 Card-Level Indicators Card-Level LEDs Description FAIL LED (Red) The red FAIL LED indicates that the card’s processor is not ready or that a catastrophic software failure occurred on the ML1000-2 card. As part of the boot sequence, the FAIL LED is turned on until the software deems the card operational. ACT LED (Green) A green ACT LED provides the operational status of the ML1000-2.
Chapter 5 Ethernet Cards 5.8.1 Compatibility by Card 5.8.1 Compatibility by Card Table 5-15 lists Cisco ONS 15454 SDH Ethernet cards with their compatible GBICs and SFPs. Caution Only use GBICs and SFPs certified for use in Cisco Optical Networking Systems. The qualified Cisco GBIC and SFP pluggable module’s top assembly numbers (TANs) are provided in Table 5-15.
Chapter 5 Ethernet Cards 5.8.2 GBIC Description GBIC dimensions are: • Height 0.39 in. (1 cm) • Width 1.18 in. (3 cm) • Depth 2.56 in. (6.5 cm) GBIC temperature ranges are: • COM—commercial operating temperature range -5•C C to 70•C • EXT—extended operating temperature range 0•C C to 85•C • IND—industrial operating temperature range -40•C C to 85•C Figure 5-7 GBICs with Clips (left) and with a Handle (right) Clip Handle Receiver Transmitter 51178 Receiver Transmitter 5.8.2.
Chapter 5 Ethernet Cards 5.8.2 GBIC Description Table 5-16 Supported Wavelengths for CWDM GBICs CWDM GBIC Wavelengths 1470 nm 1490 nm 1510 nm 1530 nm 1550 nm 1570 nm 1590 nm 1610 nm Corresponding GBIC Colors Gray Violet Blue Green Yellow Orange Red Brown Band 49 51 53 55 57 59 61 47 The ONS 15454-supported DWDM GBICs reach up to 100 to 120 km over single-mode fiber and support 32 different wavelengths in the red and blue bands.
Chapter 5 Ethernet Cards 5.8.3 SFP Description 5.8.2.1.2 Example of CWDM or DWDM GBIC Application A G-Series card equipped with CWDM or DWDM GBICs supports the delivery of unprotected Gigabit Ethernet service over Metro DWDM (Figure 5-9). It can be used in short-haul and long-haul applications.
Chapter 5 Ethernet Cards 5.8.3 SFP Description Actuator/Button SFP Figure 5-12 Bail Clasp SFP 63067 63066 Figure 5-11 Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 5 Ethernet Cards 5.8.3 SFP Description Cisco ONS 15454 SDH Reference Manual, R5.
C H A P T E R 6 Storage Access Networking Cards The FC_MR-4 card is a 1.0625- or 2.125-Gbps Fibre Channel/Fiber Connectivity (FICON) card that integrates non-SDH framed protocols into an SDH time-division multiplexing (TDM) platform through virtually concatenated payloads. This chapter provides information about the FC_MR-4 card. For installation and step-by-step circuit configuration procedures, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 6.
Chapter 6 Storage Access Networking Cards 6.1.1 FC_MR-4 Card-Level Indicators • High-order SONET/SDH VCAT support (STS1-xv/VC-3 and STS3c-xv/VC-4) Figure 6-1 shows the FC_MR-4 faceplate and block diagram.
Chapter 6 Storage Access Networking Cards 6.1.2 FC_MR-4 Port-Level Indicators 6.1.2 FC_MR-4 Port-Level Indicators Each FC_MR-4 port has a corresponding ACT/LNK LED. The ACT/LNK LED is solid green if the port is available to carry traffic, is provisioned as in-service, and in the active mode. The ACT/LNK LED is flashing green if the port is carrying traffic.
Chapter 6 Storage Access Networking Cards 6.2.2 Enhanced Card Mode 6.2.2 Enhanced Card Mode Features available in enhanced card mode are given in this section. 6.2.2.
Chapter 6 Storage Access Networking Cards 6.2.4 Interoperability Features (Enhanced Mode Only) • Insulation for FC switches from any SONET switchovers. No FC fabric reconvergences for SONET failures of less than or equal to 60 ms. 6.2.4 Interoperability Features (Enhanced Mode Only) The interoperability features are as follows: • Maximum frame size setting to prevent accumulation of oversize PMs for VSAN frames • Ingress filtering disable for attachment to third party GFP over SONET/SDH equipment 6.
Chapter 6 Storage Access Networking Cards 6.3 FC_MR-4 Card Application The FC_MR-4 payloads can be transported over the following protected circuit types, in addition to unprotected circuits: • SNCP (CCAT circuits only) • MS-SPRing • Protection channel access (PCA) The FC_MR-4 card supports high-order virtual concatenation (VCAT). See the “10.14 Virtual Concatenated Circuits” section on page 10-22.
C H A P T E R 7 Card Protection This chapter explains the Cisco ONS 15454 SDH card protection configurations. To provision card protection, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 7.1 Electrical Card Protection, page 7-1 • 7.2 STM-N Card Protection, page 7-4 • 7.3 Unprotected Cards, page 7-4 • 7.4 External Switching Commands, page 7-5 7.1 Electrical Card Protection The ONS 15454 SDH provides a variety of electrical card protection methods.
Chapter 7 Card Protection 7.1.2 1:N Protection Figure 7-1 ONS 15454 SDH Cards in a 1:1 Protection Configuration 26 28 29 Protect Working Protect Working (not electric) 12 27 Working Working Timing, Comm., and Control Cross Connect AIC-I (optional) Cross Connect Timing, Comm.
Chapter 7 Card Protection 7.1.2 1:N Protection Figure 7-2 ONS 15454 SDH Cards in a 1:N Protection Configuration 26 28 29 Working Working Working (not electric) 12 27 1:N Protection Working Working Timing, Comm., and Control Cross Connect AIC-I (optional) Cross Connect Timing, Comm.
Chapter 7 Card Protection 7.2 STM-N Card Protection The ONS 15454 SDH automatically detects and identifies a 1:N protect card when the card is installed in Slot 3 or Slot 15. However, the slot containing the 1:N card in a protection group must be manually provisioned as a protect slot because by default, all cards are working cards. 7.2 STM-N Card Protection With 1+1 port-to-port protection, any number of ports on the protect card can be assigned to protect the corresponding ports on the working card.
Chapter 7 Card Protection 7.4 External Switching Commands Figure 7-3 ONS 15454 SDH Cards in an Unprotected Configuration FMEC FMEC FMEC FMEC 23 FMEC 22 MIC-T/C/P 21 MIC-A/P 20 FMEC 19 FMEC FMEC FMEC FMEC 18 24 25 26 27 28 29 Working Working Working Working Working Working (not electric) Timing, Comm., and Control Cross Connect Timing, Comm.
Chapter 7 Card Protection 7.4 External Switching Commands Cisco ONS 15454 SDH Reference Manual, R5.
C H A P T E R 8 Cisco Transport Controller Operation This chapter describes Cisco Transport Controller (CTC), the Cisco software interface for the Cisco ONS 15454 SDH. For CTC set up and login information, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 8.1 CTC Software Delivery Methods, page 8-1 • 8.2 CTC Installation Overview, page 8-3 • 8.3 PC and UNIX Workstation Requirements, page 8-3 • 8.4 ONS 15454 SDH Connection, page 8-5 • 8.5 CTC Window, page 8-6 • 8.
Chapter 8 Cisco Transport Controller Operation 8.1.1 CTC Software Installed on the TCC2/TCC2P Card Figure 8-1 CTC Software Versions, Node View Select the Maintenance > Software tabs in network view to display the software versions installed on all the network nodes (Figure 8-2). Figure 8-2 CTC Software Versions, Network View Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 8 Cisco Transport Controller Operation 8.1.2 CTC Software Installed on the PC or UNIX Workstation 8.1.2 CTC Software Installed on the PC or UNIX Workstation CTC software is downloaded from the TCC2/TCC2P cards and installed on your computer automatically after you connect to the ONS 15454 SDH with a new software release for the first time. Downloading the CTC software files automatically ensures that your computer is running the same CTC software version as the TCC2/TCC2P cards you are accessing.
Chapter 8 Cisco Transport Controller Operation 8.3 PC and UNIX Workstation Requirements Table 8-1 JRE Compatibility ONS Software Release JRE 1.2.2 Compatible JRE 1.3 Compatible JRE 1.4 Compatible ONS 15454 SDH Release 3.3 Yes Yes No ONS 15454 SDH Release 3.4 No Yes No ONS 15454 SDH Release 4.01 No Yes No ONS 15454 SDH Release 4.1 No Yes No ONS 15454 SDH Release 4.5 No Yes No ONS 15454 SDH Release 4.6 No Yes Yes ONS 15454 SDH Release 4.
Chapter 8 Cisco Transport Controller Operation 8.4 ONS 15454 SDH Connection Table 8-2 CTC Computer Requirements (continued) Area Requirements Operating system Notes • PC: Windows 98, Windows NT 4.0, Windows 2000, or Windows XP • Workstation: Ultra 10 Sun running SunOS 6, 7, or 8 Java Runtime JRE 1.4.2 Environment — JRE 1.4.2 is installed by the CTC Installation Wizard included on the Cisco ONS 15454 SDH software and documentation CDs. JRE 1.4.
Chapter 8 Cisco Transport Controller Operation 8.5 CTC Window SDH. You can connect to the ONS 15454 SDH through a LAN or modem, and you can establish TL1 connections from a PC or TL1 terminal. Table 8-3 lists the ONS 15454 SDH connection methods and requirements.
Chapter 8 Cisco Transport Controller Operation 8.5.1 Node View Figure 8-3 Node View (Default Login View) Node view Upper FMEC shelf Menu Tool bar Status area Graphic area Tabs 102028 Subtabs Status bar 8.5.1 Node View Node view, shown in Figure 8-3, is the first view open after you log into an ONS 15454 SDH. The login node is the first node shown, and it is the “home view” for the session. Node view allows you to view and manage one ONS 15454 SDH node.
Chapter 8 Cisco Transport Controller Operation 8.5.1 Node View Table 8-4 Node View Card Colors (continued) Card Color Status Orange Slot is provisioned; a Major alarm condition exists. Red Slot is provisioned; a Critical alarm exists. The colors of the Front Mount Electrical Connection (FMEC) cards reflect the real-time status of the physical FMEC cards. Table 8-5 lists the FMEC card colors. The FMEC ports shown in CTC do not change color. Note You cannot preprovision FMECs.
Chapter 8 Cisco Transport Controller Operation 8.5.1 Node View Table 8-6 Node View Card Port Colors and Service States (continued) Port Color Service State Description Green Unlocked-enabled The port is fully operational and performing as provisioned. The port transmits a signal and displays alarms; loopbacks are not allowed. Violet Unlocked-disabled, automaticInService The port is out-of-service, but traffic is carried. Alarm reporting is suppressed.
Chapter 8 Cisco Transport Controller Operation 8.5.1 Node View The graphics on a port in node view show the state of a port (diagonal lines or loop graphics). Table 8-8 lists the port graphic and their description. Table 8-8 Node View Port Graphics Lower Shelf Port Graphics Description Multiple diagonal lines on port Port is in service and card was reset. Loop graphic on port Port is in service and has a loopback provisioned in Card View > Maintenance > Loopback tabs. 8.5.1.
Chapter 8 Cisco Transport Controller Operation 8.5.2 Network View Table 8-9 Node View Tabs and Subtabs (continued) Tab Description Inventory Provides inventory information (part number, — serial number, CLEI codes) for cards installed in the node. Allows you to delete and reset cards. Maintenance Performs maintenance tasks for the node.
Chapter 8 Cisco Transport Controller Operation 8.5.2 Network View The graphic area displays a background image with colored ONS 15454 SDH icons. A Superuser can set up the logical network view feature, which enables each user to see the same network view. The lines show DCC connections between the nodes. DCC connections can be green (active) or gray (fail). The lines can also be solid (circuits can be routed through this link) or dashed (circuits cannot be routed through this link).
Chapter 8 Cisco Transport Controller Operation 8.5.3 Card View 8.5.3 Card View Card view provides information about individual ONS 15454 SDH cards (Figure 8-7). Use this window to perform card-specific maintenance and provisioning. A graphic showing the ports on the card is shown in the graphic area. The status area displays the node name, slot, number of alarms, card type, equipment type, and the card status (active or standby), card state if the card is present, or port state (Table 8-6 on page 8-8).
Chapter 8 Cisco Transport Controller Operation 8.5.3 Card View Table 8-12 Card View Tabs and Subtabs Tab Description Alarms Lists current alarms (CR, MJ, MN) for the card — and updates them in real time. Conditions Displays a list of standing conditions on the card. — History Provides a history of card alarms including date, object, port, and severity of each alarm.
Chapter 8 Cisco Transport Controller Operation 8.6 TCC2/TCC2P Card Reset 8.6 TCC2/TCC2P Card Reset You can reset the ONS 15454 SDH TCC2/TCC2P card by using CTC (a soft reset) or by physically reseating a TCC2/TCC2P card (a hard reset). A soft reset reboots the TCC2/TCC2P card and reloads the operating system and the application software. Additionally, a hard reset temporarily removes power from the TCC2/TCC2P card and clears all buffer memory.
Chapter 8 Cisco Transport Controller Operation 8.8 Software Revert To perform a supported (non-service-affecting) revert from Software R5.0, the release you want to revert to must have been working at the time you first activated Software R5.0 on that node. Because a supported revert automatically restores the node configuration at the time of the previous activation, any configuration changes made after activation will be lost when you revert the software. Downloading Release 5.
C H A P T E R 9 Security and Timing This chapter provides information about Cisco ONS 15454 SDH users and SDH timing. To provision security and timing, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 9.1 Users and Security, page 9-1 • 9.2 Node Timing, page 9-7 9.1 Users and Security The CISCO15 user ID is provided with the ONS 15454 SDH system, but this user ID is not prompted when you sign into Cisco Transport Controller (CTC).
Chapter 9 Security and Timing 9.1.
Chapter 9 Security and Timing 9.1.
Chapter 9 Security and Timing 9.1.
Chapter 9 Security and Timing 9.1.
Chapter 9 Security and Timing 9.1.2 Security Policies 9.1.2.2 User Password, Login, and Access Policies Superusers can view real-time lists of users who are logged into CTC or TL1 by node. Superusers can also provision the following password, login, and node access policies. • Password expirations and reuse—Superusers can specify when users must change and when they can reuse their passwords.
Chapter 9 Security and Timing 9.2 Node Timing 9.2 Node Timing SDH timing parameters must be set for each ONS 15454 SDH. Each ONS 15454 SDH independently accepts its timing reference from one of three sources: • The building integrated timing supply (BITS) pins on the MIC-C/T/P coaxial connectors. • An STM-N card installed in the ONS 15454 SDH. The card is connected to a node that receives timing through a BITS source. • The internal ST3 clock on the TCC2/TCC2P card.
Chapter 9 Security and Timing 9.2.
Chapter 9 Security and Timing 9.2.2 Synchronization Status Messaging Table 9-5 SDH SSM Message Set (continued) Message Quality Description G812L 4 Local node clock traceable SETS 5 Synchronous equipment DUS 6 Do not use for timing synchronization Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 9 Security and Timing 9.2.2 Synchronization Status Messaging Cisco ONS 15454 SDH Reference Manual, R5.
C H A P T E R 10 Circuits and Tunnels This chapter explains Cisco ONS 15454 SDH high-order and low-order circuits; low-order, data communication channel (DCC), and IP-encapsulated tunnels; and virtual concatenated (VCAT) circuits. To provision circuits and tunnels, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 10.1 Overview, page 10-1 • 10.2 Circuit Properties, page 10-2 • 10.3 Cross-Connect Card Bandwidth, page 10-9 • 10.4 DCC Tunnels, page 10-10 • 10.
Chapter 10 Circuits and Tunnels 10.2 Circuit Properties • Enable port grouping on low-order path tunnels. Three ports form a port group. For example, in one E3-12 or one DS3i-N-12 card, four port groups are available: Ports 1 to 3 = PG1, Ports 4 to 6 = PG2, Ports 7 to 9 = PG3, and Ports 10 to 12 = PG4. Note CTC shows VC3-level port groups, but the XC10G creates only VC4-level port groups. VC4 tunnels must be used to transport VC3 signal rates.
Chapter 10 Circuits and Tunnels 10.2 Circuit Properties to the Cisco ONS 15454 DWDM Installation and Operations Guide for more information. Low-order VCAT circuits are VC3. For information on the number of supported members for each card, see Table 10-12. • OCHNC Wlen—For OCHNCs, the wavelength provisioned for the DWDM optical channel network connection. (DWDM only; refer to the Cisco ONS 15454 DWDM Installation and Operations Guide for more information).
Chapter 10 Circuits and Tunnels 10.2.1 Circuit Status Figure 10-1 ONS 15454 SDH Circuit Window in Network View 10.2.1 Circuit Status The circuit statuses that appear in the Circuit window Status column are generated by CTC based on conditions along the circuit path. Table 10-1 shows the statuses that can appear in the Status column. Table 10-1 ONS 15454 SDH Circuit Status Status Definition/Activity CREATING CTC is creating a circuit. DISCOVERED CTC created a circuit.
Chapter 10 Circuits and Tunnels 10.2.2 Circuit States Table 10-1 ONS 15454 SDH Circuit Status (continued) Status Definition/Activity PARTIAL A CTC-created circuit is missing a cross-connect or network span, a complete path from source to destination(s) does not exist, or an alarm interface panel (AIP) change occurred on one of the circuit nodes and the circuit is in need of repair. (AIPs store the node MAC address.) In CTC, circuits are represented using cross-connects and network spans.
Chapter 10 Circuits and Tunnels 10.2.2 Circuit States • If all cross-connects in a circuit are in the Locked-enabled,maintenance; Unlocked-disabled,automaticInService; or Locked-enabled,disabled service state, the circuit service state is Locked. • Partial is appended to the Locked circuit service state when circuit cross-connects state are mixed and not all in the Unlocked-enabled service state. The Locked-partial state can occur during automatic or manual transitions between states.
Chapter 10 Circuits and Tunnels 10.2.3 Circuit Protection Types 10.2.3 Circuit Protection Types The Protection column on the Circuit window shows the card (line) and SDH topology (path) protection used for the entire circuit path. Table 10-2 shows the protection type indicators that appear in this column. Table 10-2 Circuit Protection Types Protection Type Description 1+1 The circuit is protected by a 1+1 protection group. 2F MS-SPRing The circuit is protected by a two-fiber MS-SPRing.
Chapter 10 Circuits and Tunnels 10.2.4 Circuit Information in the Edit Circuit Window • The circuit source and destination points • Open Shortest Path First (OSPF) area IDs • Link protection (SNCP, unprotected, MS-SPRing, 1+1) and bandwidth (STM-N) For MS-SPRings, the detailed map shows the number of MS-SPRing fibers and the MS-SPRing ring ID. For SNCPs, the map shows the active and standby paths from circuit source to destination, and it also shows the working and protect paths.
Chapter 10 Circuits and Tunnels 10.3 Cross-Connect Card Bandwidth Figure 10-2 Terminal Loopback in the Edit Circuits Window Move the mouse cursor over nodes, ports, and spans to see tooltips with information including the number of alarms on a node (organized by severity), port service state, and the protection topology. Right-click a node, port, or span on the detailed circuit map to initiate certain circuit actions: • Right-click a unidirectional circuit destination node to add a drop to the circuit.
Chapter 10 Circuits and Tunnels 10.4 DCC Tunnels The XC-VXL-10G and XC-VXL-2.5G card support both low-order and high-order circuits (E-1, E-3, DS-3, STM-1, STM-4, STM-16, and STM-64 signal rates). They manage up to 192 bidirectional STM-1 cross-connects, 192 bidirectional E-3 or DS-3 cross-connects, or 1008 bidirectional E-1 cross-connects. The XC10G, XC-VXL-10G, and XC-VXL-2.5G cards work with the TCC2/TCC2P card to maintain connections and set up cross-connects within the node.
Chapter 10 Circuits and Tunnels 10.4.2 IP-Encapsulated Tunnels Note A DCC does not function on a mixed network of ONS 15454 SDH nodes and ONS 15454 nodes. DCC tunneling is required for ONS 15454 SDH nodes transporting data through ONS 15454 nodes.
Chapter 10 Circuits and Tunnels 10.5 Multiple Destinations for Unidirectional Circuits 10.5 Multiple Destinations for Unidirectional Circuits Unidirectional circuits can have multiple destinations for use in broadcast circuit schemes. In broadcast scenarios, one source transmits traffic to multiple destinations, but traffic is not returned back to the source.
Chapter 10 Circuits and Tunnels 10.7.1 Open-Ended SNCP Circuits In the SNCP Switch Counts subtab, you can: • Perform maintenance switches on the circuit selector. • View switch counts for the selectors. 10.7.1 Open-Ended SNCP Circuits If ONS 15454 SDHs are connected to a third-party network, you can create an open-ended SNCP circuit to route a circuit through it. To do this, you create three circuits. One circuit is created on the source ONS 15454 SDH network.
Chapter 10 Circuits and Tunnels 10.8 MS-SPRing Protection Channel Access Circuits Figure 10-5 SNCP Go-and-Return Routing Node A Any network Any network Go and Return working connection Go and Return protecting connection 96953 Node B 10.8 MS-SPRing Protection Channel Access Circuits You can provision circuits to carry traffic on MS-SPRing protection channels when conditions are fault free.
Chapter 10 Circuits and Tunnels 10.9 Path Trace 10.9 Path Trace SDH J1 and J2 path trace are repeated, fixed-length strings composed of 64 consecutive bytes. You can use the strings to monitor interruptions or changes to circuit traffic. Table 10-5 shows the ONS 15454 SDH cards that support J1 path trace. Cards that are not listed in the table do not support the J1 byte.
Chapter 10 Circuits and Tunnels 10.
Chapter 10 Circuits and Tunnels 10.11.1 Bandwidth Allocation and Routing • If the network has a mixture of low-order-capable nodes and low-order-incapable nodes, CTC might automatically create a low-order tunnel. Otherwise, CTC asks you whether or not a low-order tunnel is needed. 10.11.1 Bandwidth Allocation and Routing Within a given network, CTC routes circuits on the shortest possible path between source and destination based on the circuit attributes, such as protection and type.
Chapter 10 Circuits and Tunnels 10.12 Manual Circuit Routing • For point-to-point (straight) Ethernet circuits, only VC endpoints can be specified as multiple sources or drops. For bidirectional circuits, CTC creates an SNCP connection at the source node that allows traffic to be selected from one of the two sources on the ONS 15454 SDH network. If you check the Fully Path Protected option during circuit creation, traffic is protected within the ONS 15454 SDH network.
Chapter 10 Circuits and Tunnels 10.
Chapter 10 Circuits and Tunnels 10.12 Manual Circuit Routing Figure 10-10 Ethernet and SNCP Source Source Node 2 Node 5 Node 6 Node 5 SNCP Segment Drop Node 8 Node 7 Node 8 Drop 83951 Node 7 Node 6 SNCP Segment Node 11 Node 11 Legal • Illegal Low-order tunnels cannot be the endpoint of an SNCP segment. A SNCP segment endpoint is where the SNCP selector resides. If you provision full path protection, CTC verifies that the route selection is protected at all segments.
Chapter 10 Circuits and Tunnels 10.
Chapter 10 Circuits and Tunnels 10.13 Constraint-Based Circuit Routing 10.13 Constraint-Based Circuit Routing When you create circuits, you can choose Fully Protected Path to protect the circuit from source to destination. The protection mechanism used depends on the path CTC calculates for the circuit.
Chapter 10 Circuits and Tunnels 10.14.2 Software-Link Capacity Adjustment constraints for individual members; with manual routing, you can select different spans for different members. The FC_MR-4 and ML-Series cards support common fiber routing. In common fiber routing, all VCAT members travel on the same fibers, which eliminates delay between members. Three protection options are available for common fiber routing: Fully Protected, PCA, and Unprotected.
Chapter 10 Circuits and Tunnels 10.15 Merge Circuits Table 10-12 ONS 15454 SDH Card VCAT Circuit Rates and Members Card Circuit Rate Number of Members FC_MR-4 (Line rate mode) VC4 8 (1-Gbps port) 16 (2-Gbps port) FC_MR-4 (Enhanced mode) VC4 1–8 (1-Gbps port) 1–16 (2-Gbps port) ML-Series VC3, VC4, VC4-4c 2 Use the Members tab on the Edit Circuit window to add or delete members from a VCAT circuit.
Chapter 10 Circuits and Tunnels 10.16 Reconfigure Circuits • Circuit sizes must be identical. • VLAN assignments must be identical. • Circuit end points must send or receive the same framing format. • The merged circuits must become a DISCOVERED circuit. If all connections from the master circuit and all connections from the merged circuits align to form one complete circuit, the merge is successful.
Chapter 10 Circuits and Tunnels 10.16 Reconfigure Circuits Cisco ONS 15454 SDH Reference Manual, R5.
C H A P T E R 11 SDH Topologies and Upgrades This chapter explains Cisco ONS 15454 SDH topologies and upgrades. To provision topologies, refer to the Cisco ONS 15454 SDH Procedure Guide. Chapter topics include: • 11.1 SDH Rings and TCC2/TCC2P Cards, page 11-1 • 11.2 Multiplex Section-Shared Protection Rings, page 11-2 • 11.3 Subnetwork Connection Protection, page 11-13 • 11.4 Dual Ring Interconnect, page 11-18 • 11.5 Subtending Rings, page 11-26 • 11.
Chapter 11 SDH Topologies and Upgrades 11.2 Multiplex Section-Shared Protection Rings 5. See the “11.3 Subnetwork Connection Protection” section on page 11-13. 6. Total LDCC and SDCC usage must be equal to or less than 84. When LDCC is provisioned, an SDCC termination is allowed on the same port, but is not recommended. Using SDCC and LDCC on the same port is only needed during a software upgrade if the other end of the link does not support LDCC.
Chapter 11 SDH Topologies and Upgrades 11.2.1 Two-Fiber MS-SPRings Figure 11-1 Four-Node, Two-Fiber MS-SPRing VC4s 1-8 (working) VC4s 9-16 (protect) Node 0 VC4s 1-8 (working) VC4s 9-16 (protect) STM-16 Ring Node 1 = Fiber 1 Node 2 = Fiber 2 71491 Node 3 The SDH K1, K2, and K3 bytes carry the information that governs MS-SPRing protection switches. Each MS-SPRing node monitors the K bytes to determine when to switch the SDH signal to an alternate physical path.
Chapter 11 SDH Topologies and Upgrades 11.2.1 Two-Fiber MS-SPRings Figure 11-2 shows a sample traffic pattern on a four-node, two-fiber MS-SPRing. Figure 11-2 Four-Node, Two-Fiber MS-SPRing Traffic Pattern Node 0 Node 3 STM-16 Ring Node 1 Fiber 1 Node 2 Fiber 2 71276 Traffic flow Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 11 SDH Topologies and Upgrades 11.2.1 Two-Fiber MS-SPRings Figure 11-3 shows how traffic is rerouted after a line break between Node 0 and Node 3. • All circuits originating on Node 0 and carried to Node 2 on Fiber 2 are switched to the protect bandwidth of Fiber 1. For example, a circuit carried on VC4-1 on Fiber 2 is switched to VC4-9 on Fiber 1. A circuit carried on VC4-2 on Fiber 2 is switched to VC4-10 on Fiber 1. Fiber 1 carries the circuit to Node 3 (the original routing destination).
Chapter 11 SDH Topologies and Upgrades 11.2.2 Four-Fiber MS-SPRings 11.2.2 Four-Fiber MS-SPRings Four-fiber MS-SPRings double the bandwidth of two-fiber MS-SPRings. Because they allow span switching as well as ring switching, four-fiber MS-SPRings increase the reliability and flexibility of traffic protection. Two fibers are allocated for working traffic and two fibers for protection, as shown in Figure 11-4.
Chapter 11 SDH Topologies and Upgrades 11.2.2 Four-Fiber MS-SPRings Four-fiber MS-SPRings provide span and ring switching. Span switching occurs when a working span fails (Figure 11-5). Traffic switches to the protect fibers between the nodes (Node 0 and Node 1 in the Figure 11-5 example) and then returns to the working fibers that did not fail. Multiple span switches can occur at the same time.
Chapter 11 SDH Topologies and Upgrades 11.2.3 MS-SPRing Bandwidth Ring switching occurs when a span switch cannot recover traffic (Figure 11-6), such as when both the working and protect fibers fail on the same span. In a ring switch, traffic is routed to the protect fibers throughout the full ring. Figure 11-6 Four-Fiber MS-SPRing Switch Node 0 Span 4 Span 1 Span 5 Span 8 STM-16 Ring Span 6 Node 1 Span 7 Span 3 Span 2 = Working fibers Node 2 = Protect fibers 71279 Node 3 11.2.
Chapter 11 SDH Topologies and Upgrades 11.2.3 MS-SPRing Bandwidth Table 11-2 Two-Fiber MS-SPRing Capacity (continued) STM Rate Working Bandwidth Protection Bandwidth Ring Capacity STM-16 VC4 1-8 VC4 9-16 8 x N – PT STM-64 VC4 1-32 VC4 33-64 32 x N – PT 1. N equals the number of ONS 15454 SDH nodes configured as MS-SPRing nodes. 2. PT equals the number of VC4 circuits passed through ONS 15454 SDH nodes in the ring. (Capacity can vary depending on the traffic pattern.
Chapter 11 SDH Topologies and Upgrades 11.2.4 MS-SPRing Application Sample 11.2.4 MS-SPRing Application Sample Figure 11-8 shows a sample two-fiber MS-SPRing implementation with five nodes. A regional long-distance network connects to other carriers at Node 0. Traffic is delivered to the service provider’s major hubs. • Carrier 1 delivers six E-3s over two STM-1 spans to Node 0. Carrier 2 provides twelve E-3s directly.
Chapter 11 SDH Topologies and Upgrades 11.2.4 MS-SPRing Application Sample Figure 11-9 shows the shelf assembly layout for Node 0, which has one free slot. Figure 11-9 Shelf Assembly Layout for Node 0 in Figure 11-8 Lower Shelf 71270 E3-12 E3-12 OC3/STM1 OC3/STM1 OC48/STM16 OC48/STM16 TCC2 XCVXL Free Slot XCVXL TCC2 Free Slot E1-N-14 E1-N-14 E1-N-14 E1-N-14 E1-N-14 Figure 11-10 shows the shelf assembly layout for the remaining sites in the ring.
Chapter 11 SDH Topologies and Upgrades 11.2.5 MS-SPRing Fiber Connections 11.2.5 MS-SPRing Fiber Connections Plan your fiber connections and use the same plan for all MS-SPRing nodes. For example, make the east port the farthest slot to the right and the west port the farthest slot to the left. Plug fiber connected to an east port at one node into the west port on an adjacent node. Figure 11-11 shows fiber connections for a two-fiber MS-SPRing with trunk cards in Slot 5 (west) and Slot 12 (east).
Chapter 11 SDH Topologies and Upgrades 11.2.6 Two-Fiber MS-SPRing to Four-Fiber MS-SPRing Conversion Connecting Fiber to a Four-Node, Four-Fiber MS-SPRing West Node 1 Node 2 Tx Rx Tx Rx East West Slot Slot 12 13 Slot Slot 6 5 Tx Rx West East Slot Slot 12 13 Slot Slot 5 6 Node 4 Slot Slot 12 13 Slot Slot 6 5 Tx Rx East West East Slot Slot 12 13 Slot Slot 5 6 Node 3 Working fibers 958 Figure 11-12 11.2.
Chapter 11 SDH Topologies and Upgrades 11.3 Subnetwork Connection Protection CTC automates ring configuration. SNCP ring network traffic is defined within the ONS 15454 SDH on a circuit-by-circuit basis. If an extended SNCP ring mesh network circuit is not defined within a 1+1 or MS-SPRing line protection scheme and path protection is available and specified, CTC uses an SNCP ring as the default protection mechanism. An SNCP ring circuit requires two DCC-provisioned optical spans per node.
Chapter 11 SDH Topologies and Upgrades 11.3 Subnetwork Connection Protection The same signal is also sent on the protect traffic path through Node D. If a fiber break occurs (Figure 11-14), Node C switches its active receiver to the protect signal coming through Node D.
Chapter 11 SDH Topologies and Upgrades 11.3 Subnetwork Connection Protection Figure 11-15 shows a common SNCP ring application. STM-1 path circuits provide remote switch connectivity to a host V5.x switch. In the example, each remote switch requires eight E-1s to return to the host switch. Figure 11-16 on page 11-17 and Figure 11-17 on page 11-17 show the shelf layout for each node in the example. Figure 11-15 STM-1 SNCP Ring V5.
Chapter 11 SDH Topologies and Upgrades 11.3 Subnetwork Connection Protection Figure 11-16 Card Setup of Node A in the STM-1 SNCP Ring Example Lower Shelf 71265 Free Slot Free Slot Free Slot Free Slot Free Slot Free Slot TCC2 XCVXL Free Slot XCVXL TCC2 OC3/STM1 OC3/STM1 E1-N-14 E1-N-14 E1-N-14 E1-N-14 In Figure 11-15 on page 11-16, Nodes B through D each contain two E1-14 cards and two STM-1 cards. Eight free slots are available that you can provision with other cards or leave empty.
Chapter 11 SDH Topologies and Upgrades 11.4 Dual Ring Interconnect 11.4 Dual Ring Interconnect Dual ring interconnect (DRI) topology provides an extra level of path protection for circuits on interconnected rings. DRI allows users to interconnect MS-SPRings, SNCPs, or an SNCP with an MS-SPRing, with additional protection provided at the transition nodes. In a DRI topology, ring interconnections occur at two or four nodes. The drop-and-continue DRI method is used for all ONS 15454 SDH DRIs.
Chapter 11 SDH Topologies and Upgrades 11.4.1 MS-SPRing DRI Figure 11-18 shows ONS 15454 SDHs in a traditional MS-SPRing DRI topology with same-side routing. In Ring 1, Nodes 3 and 4 are the interconnect nodes, and in Ring 2, Nodes 8 and 9 are the interconnect nodes. Duplicate signals are sent between Node 4 (Ring 1) and Node 9 (Ring 2), and between Node 3 (Ring 1) and Node 8 (Ring 2).
Chapter 11 SDH Topologies and Upgrades 11.4.1 MS-SPRing DRI Figure 11-19 shows ONS 15454 SDHs in a traditional MS-SPRing DRI topology with opposite-side routing. In Ring 1, Nodes 3 and 4 are the interconnect nodes, and in Ring 2, Nodes 8 and 9 are the interconnect nodes. Duplicate signals are sent from Node 4 (Ring 1) to Node 8 (Ring 2), and between Node 3 (Ring 1) and Node 9 (Ring 2). In Ring 1, traffic at Node 4 is dropped (to Node 9) and continued (to Node 8).
Chapter 11 SDH Topologies and Upgrades 11.4.1 MS-SPRing DRI Figure 11-20 shows ONS 15454 SDHs in an integrated MS-SPRing DRI topology. The same drop-and-continue traffic routing occurs at two nodes, rather than four. This is achieved by installing an additional STM-N trunk at the two interconnect nodes. Nodes 3 and 8 are the interconnect nodes.
Chapter 11 SDH Topologies and Upgrades 11.4.2 SNCP Dual Ring Interconnect 11.4.2 SNCP Dual Ring Interconnect The SNCP dual ring interconnect topology (SNCP DRI) provides an extra level of path protection between interconnected SNCP rings. In DRIs, traffic is dropped and continued at the interconnecting nodes to eliminate single points of failure. Two DRI topologies can be implemented on the ONS 15454 SDH.
Chapter 11 SDH Topologies and Upgrades 11.4.2 SNCP Dual Ring Interconnect Figure 11-21 ONS 15454 Traditional SDH Dual Ring Interconnect E1/E3/DS3I/GigE Node #1 SNCP Ring 1 Node #3 Node #4 Node #2 Node #5 Duplicate Signals Node #6 Node #7 SNCP Ring 2 Bridge Pass-through Node E1/E3/DS3I/GigE Path Selector Primary Path - Primary Return Path - Primary Return Path - Secondary 90392 Primary Path - Secondary Figure 11-22 shows ONS 15454 SDHs in an integrated DRI topology.
Chapter 11 SDH Topologies and Upgrades 11.4.
Chapter 11 SDH Topologies and Upgrades 11.4.3 SNCP/MS-SPRing DRI Handoff Configurations 11.4.3 SNCP/MS-SPRing DRI Handoff Configurations SNCPs and MS-SPRings can also be interconnected. In SNCP/MS-SPRing DRI handoff configurations, primary and secondary nodes can be the circuit source or destination, which is useful when non-DCC optical interconnecting links are present. Figure 11-23 shows an example of an SNCP to MS-SPRing traditional DRI handoff.
Chapter 11 SDH Topologies and Upgrades 11.5 Subtending Rings Figure 11-24 shows an example of an SNCP to MS-SPRing integrated DRI handoff. Figure 11-24 ONS 15454 SDH SNCP to MS-SPRing Integrated DRI Handoff Node 5 Node 1 Node 2 SNCP Node 4 Node 3 MS-SPRing Node 7 Node 8 Node 6 Bridge 115741 Path Selector 11.5 Subtending Rings The ONS 15454 SDH supports up to 84 SDH regenerator SDCCs or 28 LDCCs with TCC2/TCC2P cards.
Chapter 11 SDH Topologies and Upgrades 11.5 Subtending Rings Figure 11-25 ONS 15454 SDH with Multiple Subtending Rings SNCP SNCP SNCP or MS-SPRing SNCP 71273 SNCP or MS-SPRing Figure 11-26 shows an SNCP ring subtending from an MS-SPRing. In this example, Node 3 is the only node serving both the MS-SPRing and SNCP ring. STM-N cards in Slots 5 and 12 serve the MS-SPRing, and STM-N cards in Slots 6 and 13 serve the SNCP ring.
Chapter 11 SDH Topologies and Upgrades 11.6 Linear ADM Configurations Figure 11-27 shows two MS-SPRings shared by one ONS 15454 SDH. Ring 1 runs on Nodes 1, 2, 3, and 4. Ring 2 runs on Nodes 4, 5, 6, and 7. Two MS-SPRing, Ring 1 and Ring 2, are provisioned on Node 4. Ring 1 uses cards in Slots 5 and 12, and Ring 2 uses cards in Slots 6 and 13. Nodes in different MS-SPRings can have the same or different node IDs.
Chapter 11 SDH Topologies and Upgrades 11.7 Extended SNCP Mesh Networks Node 1 Linear (Point-to-Point) ADM Configuration Slot 5 to Slot 5 Slot 12 to Slot 12 Slot 6 to Slot 6 Slot 13 to Slot 13 Node 2 34284 Figure 11-28 Node 3 Protect Path Working Path 11.7 Extended SNCP Mesh Networks In addition to single MS-SPRings, SNCP rings, and ADMs, you can extend ONS 15454 SDH traffic protection by creating extended SNCP mesh networks.
Chapter 11 SDH Topologies and Upgrades 11.7 Extended SNCP Mesh Networks Figure 11-29 Extended SNCP Mesh Network Source Node Node 3 Node 5 Node 2 Node 4 Node 1 Node 10 Node 8 Node 6 Node 7 Node 11 Node 9 ffic g tra kin Wor Destination Node = Primary path = Secondary path 32136 Protect traffic Extended SNCP rings also allow spans with different SDH speeds to be mixed together in “virtual rings.” Figure 11-30 shows Nodes 1, 2, 3, and 4 in a standard STM-16 ring.
Chapter 11 SDH Topologies and Upgrades 11.8 Four Node Configurations 11.8 Four Node Configurations You can link multiple ONS 15454 SDHs using their STM-N cards (that is, create a fiber-optic bus) to accommodate more access traffic than a single ONS 15454 SDH can support. Refer to the Cisco ONS 15454 SDH Procedure Guide for more information. You can link nodes with STM-4 or STM-16 fiber spans as you would link any other two network nodes.
Chapter 11 SDH Topologies and Upgrades 11.9.1 Span Upgrade Wizard 11.9.1 Span Upgrade Wizard The Span Upgrade Wizard automates all steps in the manual span upgrade procedure (MS-SPRing, SNCP ring, and 1+1). The wizard can upgrade both lines on one side of a four-fiber MS-SPRing or both lines of a 1+1 group; the wizard upgrades SNCP rings and two-fiber MS-SPRings one line at a time. The Span Upgrade Wizard requires that spans have DCCs enabled.
C H A P T E R 12 CTC Network Connectivity This chapter provides nine scenarios showing Cisco ONS 15454 SDH nodes in common IP network configurations as well as information about provisionable patchcords, the routing table, external firewalls, and open gateway network element (GNE) networks. The chapter does not provide a comprehensive explanation of IP networking concepts and procedures. For IP set up instructions, refer to the “Turn Up Node” chapter of the Cisco ONS 15454 SDH Procedure Guide.
Chapter 12 CTC Network Connectivity 12.2 IP Addressing Scenarios • The ONS 15454 SDH proxy server can control the visibility and accessibility between CTC computers and ONS 15454 SDH element nodes. 12.2 IP Addressing Scenarios ONS 15454 SDH IP addressing generally has eight common scenarios or configurations. Use the scenarios as building blocks for more complex network configurations. Table 12-1 provides a general list of items to check when setting up ONS 15454 SDH nodes in IP networks.
Chapter 12 CTC Network Connectivity 12.2.2 Scenario 2: CTC and ONS 15454 SDH Nodes Connected to a Router Figure 12-1 Scenario 1: CTC and ONS 15454 SDH Nodes on the Same Subnet CTC Workstation IP Address 192.168.1.100 Subnet Mask 255.255.255.0 Default Gateway = N/A Host Routes = N/A LAN A ONS 15454 SDH #2 IP Address 192.168.1.20 Subnet Mask 255.255.255.0 Default Router = N/A Static Routes = N/A SDH RING ONS 15454 SDH #3 IP Address 192.168.1.30 Subnet Mask 255.255.255.
Chapter 12 CTC Network Connectivity 12.2.3 Scenario 3: Using Proxy ARP to Enable an ONS 15454 SDH Gateway Figure 12-2 Scenario 2: CTC and ONS 15454 SDH Nodes Connected to Router LAN A Int "A" CTC Workstation IP Address 192.168.1.100 Subnet Mask 255.255.255.0 Default Gateway = 192.168.1.1 Host Routes = N/A Int "B" Router IP Address of interface “A” to LAN “A” 192.168.1.1 IP Address of interface “B” to LAN “B” 192.168.2.1 Subnet Mask 255.255.255.
Chapter 12 CTC Network Connectivity 12.2.3 Scenario 3: Using Proxy ARP to Enable an ONS 15454 SDH Gateway Scenario 3 is similar to Scenario 1, but only one ONS 15454 SDH (#1) connects to the LAN (Figure 12-3). Two ONS 15454 SDH nodes (#2 and #3) connect to ONS 15454 SDH #1 through the SDH DCC. Because all three nodes are on the same subnet, proxy ARP enables ONS 15454 SDH #1 to serve as a gateway for ONS 15454 SDH #2 and #3. Note This scenario assumes all CTC connections are to ONS 15454 SDH #1.
Chapter 12 CTC Network Connectivity 12.2.4 Scenario 4: Default Gateway on CTC Computer In Figure 12-4, ONS 15454 SDH #1 announces to ONS 15454 SDH #2 and #3 that it can reach the CTC host. Similarly, ONS 15454 SDH #3 announces that it can reach the ONS 152xx. The ONS 152xx is shown as an example; any network element can be set up as an additional host. Figure 12-4 Scenario 3: Using Proxy ARP with Static Routing CTC Workstation IP Address 192.168.1.100 Subnet Mark at CTC Workstation 255.255.255.
Chapter 12 CTC Network Connectivity 12.2.5 Scenario 5: Using Static Routes to Connect to LANs Figure 12-5 Scenario 4: Default Gateway on a CTC Computer CTC Workstation IP Address 192.168.1.100 Subnet Mask at CTC Workstation 255.255.255.0 Default Gateway = 192.168.1.10 Host Routes = N/A LAN A ONS 15454 SDH #1 IP Address 192.168.1.10 Subnet Mask 255.255.255.0 Default Router = N/A Static Routes = N/A SDH RING ONS 15454 SDH #3 IP Address 192.168.3.30 Subnet Mask 255.255.255.
Chapter 12 CTC Network Connectivity 12.2.5 Scenario 5: Using Static Routes to Connect to LANs Figure 12-6 Scenario 5: Static Route With One CTC Computer Used as a Destination Static Routes: Destination = 192.168.0.0 Destination = 192.168.4.0 Mask = 255.255.255.0 Mask = 255.255.255.0 Next Hop = 192.168.5.1 Next Hop = 192.168.5.1 LAN A Int "A" CTC Workstation IP Address 192.168.1.100 Subnet Mask 255.255.255.0 Default Gateway = 192.168.1.
Chapter 12 CTC Network Connectivity 12.2.6 Scenario 6: Using OSPF Figure 12-7 Scenario 5: Static Route With Multiple LAN Destinations Router #2: IP Address of the interface connected to LAN-A = 192.168.1.10 IP Address of the interface connected to LAN-C = 192.168.5.1 Subnet Mask = 255.255.255.0 Static Routes: Destination = 192.168.0.0 Destination = 192.168.4.0 Mask = 255.255.255.0 Mask = 255.255.255.0 Next Hop = 192.168.1.1 Next Hop = 192.168.5.1 LAN A CTC Workstation IP Address 192.168.1.
Chapter 12 CTC Network Connectivity 12.2.6 Scenario 6: Using OSPF ONS 15454 SDH nodes use the OSPF protocol in internal ONS 15454 SDH networks for node discovery, circuit routing, and node management. You can enable OSPF on the ONS 15454 SDH nodes so that the ONS 15454 SDH topology is sent to OSPF routers on a LAN. Advertising the ONS 15454 SDH network topology to LAN routers eliminates the need to enter static routes for ONS 15454 SDH subnetworks manually.
Chapter 12 CTC Network Connectivity 12.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server Figure 12-9 shows the same network as Figure 12-8 on page 12-10without OSPF. Static routes must be manually added to the router for CTC computers on LAN A to communicate with Nodes 2 and 3 because these nodes reside on different subnets. Figure 12-9 Scenario 6: OSPF Not Enabled LAN A Int "A" CTC Workstation IP Address 192.168.1.100 Subnet Mask 255.255.255.0 Default Gateway = 192.168.1.
Chapter 12 CTC Network Connectivity 12.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server network elements (ENEs). The GNE tunnels connections between CTC computers and ENE ONS 15454 SDH nodes, providing management capability while preventing access for non-ONS 15454 SDH management purposes. The ONS 15454 SDH proxy server performs the following tasks: • Isolates DCC IP traffic from Ethernet (craft port) traffic and accepts packets based on filtering rules.
Chapter 12 CTC Network Connectivity 12.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server Figure 12-10 Proxy Server Gateway Settings Figure 12-11 shows an ONS 15454 SDH proxy server implementation. A GNE ONS 15454 SDH is connected to a central office LAN and to ENE ONS 15454 SDH nodes. The central office LAN is connected to a NOC LAN, which has CTC computers. The NOC CTC computer and craft technicians must be able to access the ONS 15454 SDH ENEs.
Chapter 12 CTC Network Connectivity 12.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server Figure 12-11 Scenario 7: SDH Proxy Server with GNE and ENEs on the Same Subnet Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 10.10.10.0/24 ONS 15454 SDH GNE 10.10.10.100/24 ONS 15454 SDH ENE 10.10.10.150/24 ONS 15454 SDH ENE 10.10.10.250/24 ONS 15454 SDH ENE 10.10.10.200/24 SDH 78236 Ethernet Local/Craft CTC 192.168.20.
Chapter 12 CTC Network Connectivity 12.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server Figure 12-12 Scenario 7: ONS 15454 SDH Proxy Server with GNE and ENEs on Different Subnets Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 10.10.10.0/24 ONS 15454 SDH GNE 10.10.10.100/24 ONS 15454 SDH ENE 192.168.10.150/24 ONS 15454 SDH ENE 192.168.10.250/24 ONS 15454 SDH ENE 192.168.10.200/24 SDH 78237 Ethernet Local/Craft CTC 192.168.20.
Chapter 12 CTC Network Connectivity 12.2.7 Scenario 7: Provisioning the ONS 15454 SDH Proxy Server Figure 12-13 shows the implementation with ONS 15454 SDH ENEs in multiple rings. In the example, ONS 15454 SDH GNEs and ENEs are provisioned with the settings shown in Table 12-2 on page 12-14. Figure 12-13 Scenario 7: ONS 15454 SDH Proxy Server With ENEs on Multiple Rings Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 10.10.10.0/24 ONS 15454 SDH GNE 10.10.
Chapter 12 CTC Network Connectivity 12.2.8 Scenario 8: Dual GNEs on a Subnet If the packet is addressed to the ONS 15454 SDH, additional rules shown in Table 12-4 apply. Rejected packets are silently discarded.
Chapter 12 CTC Network Connectivity 12.2.8 Scenario 8: Dual GNEs on a Subnet Figure 12-14 Scenario 8: Dual GNEs on the Same Subnet Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 ONS 15454 SDH 10.10.10.100/24 ONS 15454 SDH 10.10.10.150/24 ONS 15454 SDH 10.10.10.250/24 ONS 15454 SDH 10.10.10.200/24 Ethernet Local/Craft CTC 192.168.20.20 SDH 115275 10.10.10.0/24 Cisco ONS 15454 SDH Reference Manual, R5.
Chapter 12 CTC Network Connectivity 12.2.9 Scenario 9: IP Addressing with Secure Mode Enabled Figure 12-15 shows a network with dual GNEs on different subnets. Figure 12-15 Scenario 8: Dual GNEs on Different Subnets Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/2 10.20.10.1 10.10.10.0/24 10.20.10.0/24 ONS 15454 SDH 10.20.10.100/24 ONS 15454 SDH 10.10.10.100/24 ONS 15454 SDH 192.168.10.200/24 ONS 15454 SDH 192.168.10.250/24 Ethernet Local/Craft CTC 192.168.20.
Chapter 12 CTC Network Connectivity 12.2.9 Scenario 9: IP Addressing with Secure Mode Enabled Figure 12-16 shows an example of ONS 15454 SDH nodes on the same subnet with secure mode enabled.In the example, TCC2P port addresses are on a different subnet from the node MIC-C/T/P IP addresses. Note Secure mode is not available if TCC2 cards are installed, or if only one TCC2P card is installed. Figure 12-16 Scenario 9: ONS 15454 SDH GNE and ENEs on the Same Subnet with Secure Mode Enabled Remote CTC 10.
Chapter 12 CTC Network Connectivity 12.3 Provisionable Patchcords Figure 12-17 shows an example of ONS 15454 nodes connected to a router with secure mode enabled. In the example, TCC2P port addresses are on a different subnet from the node MIC-C/T/P IP addresses. Figure 12-17 Scenario 9: ONS 15454 SDH GNE and ENEs on Different Subnets with Secure Mode Enabled Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 10.10.10.
Chapter 12 CTC Network Connectivity 12.3 Provisionable Patchcords Provisionable patchcords are required on both ends of a physical link. The provisioning at each end includes a local patchcord ID, slot/port information, remote IP address, and remote patchcord ID. Patchcords appear as dashed lines in CTC network view. Table 12-5 lists the supported card combinations for client and trunk ports in a provisionable patchcord.
Chapter 12 CTC Network Connectivity 12.4 Routing Table Table 12-7 lists the supported card combinations for trunk-to-trunk ports in a patchcord. Table 12-7 Cisco ONS 15454 SDH Trunk/Trunk Card Combinations for Provisionable Patchcords MXP_2.5G_10G/ TXP_MR_10G TXP(P)_MR_2.5G MXP_2.5G_10E/ TXP_MR_10E MXP_2.5G_10G/ TXP_MR_10G Yes — Yes TXP(P)_MR_2.5G — Yes — MXP_2.
Chapter 12 CTC Network Connectivity 12.4 Routing Table • Interface—Shows the ONS 15454 SDH interface used to access the destination. Values are: – motfcc0—The ONS 15454 SDH Ethernet interface, that is, the RJ-45 jack on the TCC2/TCC2P card and the LAN connection on the MIC-C/T/P FMEC – pdcc0—An SDCC interface, that is, an STM-N trunk card identified as the SDCC termination – lo0—A loopback interface Table 12-8 shows sample routing entries for an ONS 15454 SDH.
Chapter 12 CTC Network Connectivity 12.5 External Firewalls • Gateway (0.0.0.0) means the destination host is directly attached to the node. • Interface (pdcc0) indicates that a SDH SDCC interface is used to reach the destination host. Entry 5 shows a DCC-connected node that is accessible through a node that is not directly connected: • Destination (172.20.214.94) is the destination host IP address. • Mask (255.255.255.255) is a 32-bit mask, meaning only the 172.20.214.94 address is a destination.
Chapter 12 CTC Network Connectivity 12.5 External Firewalls Table 12-9 Ports Used by the TCC2/TCC2P (continued) Port Function Action1 10240-12287 Proxy client D 57790 Default TCC listener port OK 1. D = deny, NA = not applicable, OK = do not deny The following access control list (ACL) example shows a firewall configuration when the proxy server gateway setting is not enabled. In the example, the CTC workstation's address is 192.168.10.10. and the ONS 15454 SDH address is 10.10.10.
Chapter 12 CTC Network Connectivity 12.6 Open GNE access-list 101 remark access-list 101 permit tcp host 10.10.10.100 any host 192.168.10.10 eq 683 access-list 101 remark *** allows alarms and other communications from the 15454 SDH (random port) to the CTC workstation (port 683) *** access-list 100 remark access-list 101 permit tcp host 10.10.10.100 host 192.168.10.10 established access-list 101 remark *** allows ACKs from the 15454 SDH GNE to CTC *** 12.
Chapter 12 CTC Network Connectivity 12.6 Open GNE Figure 12-18 Proxy and Firewall Tunnels for Foreign Terminations Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 ONS 15454 SDH Gateway NE 10.10.10.100/24 ONS 15454 SDH External NE 10.10.10.150/24 ONS 15454 SDH External NE 10.10.10.250/24 ONS 15454 SDH External NE 10.10.10.200/24 Non-ONS node Foreign NE 130.94.122.199/28 Ethernet Local/Craft CTC 192.168.20.20 SDH 115759 10.10.10.
Chapter 12 CTC Network Connectivity 12.6 Open GNE Figure 12-19 shows a remote node connected to an ENE Ethernet port. Proxy and firewall tunnels are useful in this example because the GNE would otherwise block IP access between the PC and foreign node. This configuration also requires a firewall tunnel on the ENE. Figure 12-19 Foreign Node Connection to an ENE Ethernet Port Remote CTC 10.10.20.10 10.10.20.0/24 Interface 0/0 10.10.20.1 Router A Interface 0/1 10.10.10.1 ONS 15454 SDH Gateway NE 10.10.10.
Chapter 12 CTC Network Connectivity 12.6 Open GNE Cisco ONS 15454 SDH Reference Manual, R5.
C H A P T E R 13 Alarm Monitoring and Management This chapter explains how to manage alarms with Cisco Transport Controller (CTC). To troubleshoot specific alarms, refer to the Cisco ONS 15454 SDH Troubleshooting Guide. Chapter topics include: • 13.1 Overview, page 13-1 • 13.2 Documenting Existing Provisioning, page 13-1 • 13.3 Viewing Alarm Counts on the LCD for a Node, Slot, or Port, page 13-2 • 13.4 Viewing Alarms, page 13-3 • 13.5 Alarm Severities, page 13-10 • 13.
Chapter 13 Alarm Monitoring and Management 13.3 Viewing Alarm Counts on the LCD for a Node, Slot, or Port Whether you choose to print or export data, you can choose from the following options: • Entire frame—Prints or exports the entire CTC window including the graphical view of the card, node, or network. This option is available for all windows. • Tabbed view—Prints or exports the lower half of the CTC window containing tabs and data.
Chapter 13 Alarm Monitoring and Management 13.4 Viewing Alarms Shelf LCD Panel Status Slot Port 8/18/03 24˚C 04.06-002L-10 FAN FAIL CRIT MAJ MIN 97758 Figure 13-1 13.4 Viewing Alarms In the card-, node-, or network-level CTC view, click the Alarms tab to display the alarms for that card, node, or network. The Alarms window shows alarms in conformance with ITU-T G.783.
Chapter 13 Alarm Monitoring and Management 13.4 Viewing Alarms Table 13-1 Alarms Column Descriptions (continued) Column Information Recorded Num Num (number) is the quantity of alarm messages received, and is incremented automatically as alarms occur to display the current total of received error messages. Ref Ref (reference) is a unique identification number assigned to each alarm to reference a specific alarm message that is displayed.
Chapter 13 Alarm Monitoring and Management 13.4.1 Viewing Alarms With Each Node’s Time Zone 13.4.1 Viewing Alarms With Each Node’s Time Zone By default, alarms and conditions are displayed with the time stamp of the CTC workstation where you are viewing them. But you can set the node to report alarms (and conditions) using the time zone where the node is located by clicking Edit > Preferences, and clicking the Display Events Using Each Node’s Timezone check box. 13.4.
Chapter 13 Alarm Monitoring and Management 13.4.4 Viewing Alarm-Affected Circuits 13.4.4 Viewing Alarm-Affected Circuits A user can view which ONS 15454 SDH circuits are affected by a specific alarm by positioning the cursor over the alarm in the Alarm window and right-clicking. A shortcut menu is displayed (Figure 13-2). Figure 13-2 Select Affected Circuits Option 124986 05.00-003J-08.
Chapter 13 Alarm Monitoring and Management 13.4.5 Conditions Tab 13.4.5 Conditions Tab The Conditions window displays retrieved fault conditions. A condition is a fault or status detected by ONS 15454 SDH hardware or software. When a condition occurs and continues for a minimum period, CTC raises a condition, which is a flag showing that this particular condition currently exists on the ONS 15454 SDH. The Conditions window shows all conditions that occur, including those that are superseded.
Chapter 13 Alarm Monitoring and Management 13.4.7 Viewing History 13.4.6.2 Conditions Column Descriptions Table 13-6 lists the Conditions window column headings and the information recorded in each column. Table 13-6 Conditions Column Description Column Information Recorded New Indicates a new condition. Date Date and time of the condition. Object The object for an HPmon or LPmon. Eqpt Type Card type in this slot.
Chapter 13 Alarm Monitoring and Management 13.4.7 Viewing History Note In the Preference dialog General tab, the Maximum History Entries value only applies to the Session window. Different views of CTC display the following kinds of history: Tip • The History > Session window is shown in network view, node view, and card view. It shows alarms and conditions that occurred during the current user CTC session. • The History > Node window is only shown in node view.
Chapter 13 Alarm Monitoring and Management 13.5 Alarm Severities 13.4.7.2 Retrieving and Displaying Alarm and Condition History You can retrieve and view the history of alarms and conditions, as well as transients (passing notifications of processes as they occur) in the CTC history window. The information in this window is specific to the view where it is shown (that is, network history in the network view, node history in the node view, and card history in the card view).
Chapter 13 Alarm Monitoring and Management 13.6.1 Creating and Modifying Alarm Profiles If one or more alarm profiles have been stored as files from elsewhere in the network onto the local PC or server hard drive where CTC resides, you can utilize as many profiles as you can physically store by deleting and replacing them locally in CTC so that only eight are active at any given time. 13.6.
Chapter 13 Alarm Monitoring and Management 13.6.2 Alarm Profile Buttons 13.6.2 Alarm Profile Buttons The Alarm Profiles window displays six buttons at the bottom. Table 13-8 lists and describes each of the alarm profile buttons and their functions. Table 13-8 Alarm Profile Buttons Button Description New Adds a new alarm profile. Load Loads a profile to a node or a file. Store Saves profiles on a node (or nodes) or in a file. Delete Deletes profiles from a node.
Chapter 13 Alarm Monitoring and Management 13.6.5 Row Display Options • Use Default • Transient (T) Transient and Use Default severity alarms only appear in alarm profiles. They do not appear when you view alarms, history, or conditions. 13.6.
Chapter 13 Alarm Monitoring and Management 13.7 Suppressing Alarms Figure 13-4 Card View Port Alarm Profile for an OPT-BST Card 13.7 Suppressing Alarms ONS 15454 SDH nodes have an alarm suppression option that clears raised alarm messages for the node, chassis, one or more slots (cards), or one or more ports. After they are cleared, these alarms change appearance from their normal severity color to white and they can be cleared from the display by clicking Synchronize.
Chapter 13 Alarm Monitoring and Management 13.8 Provisioning External Alarms and Controls 13.8 Provisioning External Alarms and Controls External alarm inputs can be provisioned on the Alarm Interface Controller-International (AIC-I) card for external sensors such as an open door and flood sensors, temperature sensors, and other environmental conditions. External control outputs on this card allow you to drive external visual or audible devices such as bells and lights.
Chapter 13 Alarm Monitoring and Management 13.9 Audit Trail – Virtual wire entities—You can provision an alarm that is input to a virtual wire to trigger an external control output. 13.9 Audit Trail The ONS 15454 SDH maintains an audit trail log that resides on the TCC2/TCC2P. This record shows who has accessed the system and what operations were performed during a given time period.
Chapter 13 Alarm Monitoring and Management 13.9.2 Audit Trail Capacities When the log server reaches a maximum capacity of 640 entries and begins overwriting records that were not archived, an AUD-LOG-LOSS condition is raised and logged. This event indicates that audit trail records have been lost. Until the user off-loads the file, this event occurs once regardless of the amount of entries that are overwritten by the system. To export the audit trail log, refer to the Cisco ONS 15454 SDH Procedure Guide.
Chapter 13 Alarm Monitoring and Management 13.9.2 Audit Trail Capacities Cisco ONS 15454 SDH Reference Manual, R5.
REVIEW DRAFT—CISCO CONFIDENTIAL CH A P T E R 14 Ethernet Operation The Cisco ONS 15454 SDH integrates Ethernet into an SDH time-division multiplexing (TDM) platform. The ONS 15454 SDH supports E-Series, G-Series, and ML-Series Ethernet cards. This chapter covers the operation of the E-Series and G-Series Ethernet cards. For information on the ML-Series cards, refer to the Cisco ONS 15454 SONET/SDH ML-Series Multilayer Ethernet Card Software Feature and Configuration Guide.
Chapter 14 Ethernet Operation 14.1.1 G1K-4 and G1000-4 Comparison REVIEW DRAFT—CISCO CONFIDENTIAL The G-Series cards allow an Ethernet private line service to be provisioned and managed very much like a traditional SDH or SONET line. G-Series card applications include providing carrier-grade transparent LAN services (TLS), 100 Mbps Ethernet private line services (when combined with an external 100-Mb Ethernet switch with Gigabit uplinks), and high-availability transport.
Chapter 14 Ethernet Operation 14.1.3 IEEE 802.3z Flow Control and Frame Buffering REVIEW DRAFT—CISCO CONFIDENTIAL The G-Series card discards certain types of erroneous Ethernet frames rather than transport them over SDH. Erroneous Ethernet frames include corrupted frames with cyclic redundancy checking (CRC) errors and under-sized frames that do not conform to the minimum 64-byte length Ethernet standard. The G-Series card forwards valid frames unmodified over the SDH network.
Chapter 14 Ethernet Operation 14.1.4 Ethernet Link Integrity Support REVIEW DRAFT—CISCO CONFIDENTIAL 14.1.4 Ethernet Link Integrity Support The G-Series supports end-to-end Ethernet link integrity (Figure 14-2). This capability is integral to providing an Ethernet private line service and correct operation of Layer 2 and Layer 3 protocols on the attached Ethernet devices. End-to-end Ethernet link integrity essentially means that if any part of the end-to-end path fails, the entire path fails.
Chapter 14 Ethernet Operation 14.2 G-Series Gigabit Ethernet Transponder Mode REVIEW DRAFT—CISCO CONFIDENTIAL G-Series Gigabit EtherChannel (GEC) Support el ann it igab rCh Ethe SDH Giga bit E ther G ONS 15454 SDH ONS 15454 SDH Cha nne l 71335 Figure 14-3 Although the G-Series card does not actively run GEC, it supports the end-to-end GEC functionality of attached Ethernet devices.
Chapter 14 Ethernet Operation 14.
Chapter 14 Ethernet Operation 14.2.1 Two-Port Bidirectional Transponder REVIEW DRAFT—CISCO CONFIDENTIAL In transponder mode, the G-Series Ethernet traffic never comes into contact with the cross-connect card or the SDH network, but stays internal to the G-Series card and is routed back to a GBIC on that card (Figure 14-6).
Chapter 14 Ethernet Operation 14.2.2 One-Port Bidirectional Transponder REVIEW DRAFT—CISCO CONFIDENTIAL 14.2.2 One-Port Bidirectional Transponder One-port bidirectional transponder mode maps the Ethernet frames received at a port out the transmitter of the same port (Figure 14-7). This mode is similar to two-port bidirectional transponder mode except that a port is mapped only to itself instead of to another port.
Chapter 14 Ethernet Operation 14.2.4 G-Series Transponder Mode Characteristics REVIEW DRAFT—CISCO CONFIDENTIAL Figure 14-8 Two-Port Unidirectional Transponder X WDM Lambda 1 X X WDM Lambda 2 X Ethernet TDM G-Series Card Cross-Connect Card Optical Card ONS Node Tx Port Rx Port GBIC CWDM or DWDM Tx Port Rx Port Note: This configuration must be used when the client terminal's optical signal is multimode, 850 nm. 90912 GBIC Standard SX, LX, ZX Unused Port X 14.2.
Chapter 14 Ethernet Operation 14.3 E-Series Application REVIEW DRAFT—CISCO CONFIDENTIAL The operation of a G-Series card in transponder mode is also similar to the operation of a G-Series card in SDH mode: • G-Series Ethernet statistics are available for ports in both modes. • Ethernet port level alarms and conditions are available for ports in both modes. • Jumbo frame and non-jumbo frame operation is the same in both modes.
Chapter 14 Ethernet Operation 14.3.
Chapter 14 Ethernet Operation 14.3.2 E-Series IEEE 802.3z Flow Control REVIEW DRAFT—CISCO CONFIDENTIAL because the E1000-2-G has a maximum bandwidth of VC4-4c. Ethernet frame sizes up to 1522 bytes are also supported, which allows transport of IEEE 802.1Q tagged frames. The larger maximum frame size of Q-in-Q frames (802.1Q in 802.1Q wrapped frames) are not supported.
Chapter 14 Ethernet Operation 14.3.3 E-Series VLAN Support REVIEW DRAFT—CISCO CONFIDENTIAL Note To enable flow control between an E-Series in port-mapped mode and a SmartBits test set, manually set bit 5 of the MII register to 0 on the SmartBits test set. To enable flow control between an E-Series in port-mapped mode and an Ixia test set, select Enable the flow control in the Properties menu of the attached Ixia port. 14.3.
Chapter 14 Ethernet Operation 14.3.4 E-Series Q-Tagging (IEEE 802.1Q) REVIEW DRAFT—CISCO CONFIDENTIAL Figure 14-12 Q-Tag Moving through VLAN Data Flow Q-tag The receiving ONS node removes the Q-tag and forwards the frame to the specific VLAN. Example 1. The ONS node uses a Q-tag internally to deliver the frame to a specific VLAN. Q-tag Example 2. The ONS node receives a frame with a Q-tag and passes it on.
Chapter 14 Ethernet Operation 14.3.5 E-Series Priority Queuing (IEEE 802.1Q) REVIEW DRAFT—CISCO CONFIDENTIAL 14.3.5 E-Series Priority Queuing (IEEE 802.1Q) Networks without priority queuing handle all packets on a FIFO basis. Priority queuing reduces the impact of network congestion by mapping Ethernet traffic to different priority levels. The ONS 15454 SDH supports priority queuing. The ONS 15454 SDH maps the eight priorities specified in IEEE 802.
Chapter 14 Ethernet Operation 14.3.6 E-Series Spanning Tree (IEEE 802.1D) REVIEW DRAFT—CISCO CONFIDENTIAL Note IEEE 802.1Q was formerly IEEE 802.1P. Note E-Series cards in port-mapped mode and G-Series cards do not support priority queing (IEEE 8021.Q). 14.3.6 E-Series Spanning Tree (IEEE 802.1D) The Cisco ONS 15454 SDH operates Spanning Tree Protocol (STP) according to IEEE 802.1D when an Ethernet card is installed.
Chapter 14 Ethernet Operation 14.3.6 E-Series Spanning Tree (IEEE 802.1D) REVIEW DRAFT—CISCO CONFIDENTIAL Spanning Tree Map on the Circuit Window 78843 Figure 14-15 Note Green represents forwarding spans and purple represents blocked (protect) spans. If you have a packet ring configuration, at least one span should be purple. Caution Multiple circuits with STP protection enabled will incur blocking if the circuits traverse a common card and use the same VLAN.
Chapter 14 Ethernet Operation 14.3.6 E-Series Spanning Tree (IEEE 802.1D) REVIEW DRAFT—CISCO CONFIDENTIAL 14.3.6.2 Spanning Tree on a Circuit-by-Circuit Basis You can also disable or enable STP on a circuit-by-circuit basis on single-card EtherSwitch E-Series cards in a point-to-point configuration. This feature allows customers to mix spanning tree protected circuits with unprotected circuits on the same card.
Chapter 14 Ethernet Operation 14.4 G-Series Circuit Configurations REVIEW DRAFT—CISCO CONFIDENTIAL 14.4 G-Series Circuit Configurations This section explains G-Series point-to-point circuits and manual cross-connects. Ethernet manual cross-connects allow you to cross connect individual Ethernet circuits to an STM-N channel on the ONS 15454 SDH optical interface and also to bridge non-ONS SDH network segments. 14.4.
Chapter 14 Ethernet Operation 14.5 E-Series Circuit Configurations REVIEW DRAFT—CISCO CONFIDENTIAL Note In this chapter, “cross-connect” and “circuit” have the following meanings: Cross-connect refers to the connections that occur within a single ONS 15454 SDH to allow a circuit to enter and exit an ONS 15454 SDH. Circuit refers to the series of connections from a traffic source (where traffic enters the ONS 15454 SDH network) to the drop or destination (where traffic exits an ONS 15454 SDH network).
Chapter 14 Ethernet Operation 14.5.2 E-Series Point-to-Point Ethernet Circuits REVIEW DRAFT—CISCO CONFIDENTIAL 14.5.2 E-Series Point-to-Point Ethernet Circuits The ONS 15454 SDH can set up a point-to-point (straight) Ethernet circuit as single-card, port-mapped or multicard circuit. Multicard EtherSwitch limits bandwidth to VC4-3c between two Ethernet circuit points, but allows adding nodes and cards and making a shared packet ring (Figure 14-18).
Chapter 14 Ethernet Operation 14.5.3 E-Series Shared Packet Ring Ethernet Circuits REVIEW DRAFT—CISCO CONFIDENTIAL 14.5.3 E-Series Shared Packet Ring Ethernet Circuits A shared packet ring allows nodes other than the source and destination nodes to access an Ethernet STM circuit. The E-Series card ports on the additional nodes can share the circuit’s VLAN and bandwidth. Figure 14-20 illustrates a shared packet ring. Your network architecture may differ from the example.
Chapter 14 Ethernet Operation 14.5.5 E-Series Ethernet Manual Cross-Connects REVIEW DRAFT—CISCO CONFIDENTIAL Figure 14-21 Hub-and-Spoke Ethernet Circuit 192.168.1.75 255.255.255.0 VLAN test 192.168.1.125 255.255.255.0 VLAN test 192.168.1.100 255.255.255.0 VLAN test 192.168.1.25 255.255.255.0 VLAN test ONS 15454 SDH #2 ONS 15454 SDH #3 192.168.1.50 255.255.255.0 VLAN test 71326 ONS 15454 SDH #1 14.5.
Chapter 14 Ethernet Operation 14.
Chapter 14 Ethernet Operation 14.
Chapter 14 Ethernet Operation 14.
A P P E N D I X A Hardware Specifications This appendix contains hardware and software specifications for the ONS 15454 SDH. A.1 Shelf Specifications This section provides specifications for shelf bandwidth; a list of topologies; Cisco Transport Controller (CTC) specifications; LAN, TL1, modem, alarm, and electrical interface assembly (EIA) interface specifications; database, timing, power, and environmental specifications; and shelf dimensions. A.1.
Appendix A Hardware Specifications A.1.3 Cisco Transport Controller • Regenerator mode • Wavelength multiplexer A.1.3 Cisco Transport Controller CTC, the ONS 15454 SDH craft interface software, has the following specifications: • 10BaseT • TCC2/TCC2P access: RJ-45 connector • Front Mount Electrical Connection (FMEC) access: LAN connector on MIC-C/T/P faceplate A.1.
Appendix A Hardware Specifications A.1.8 System Timing A.1.8 System Timing The ONS 15454 SDH has the following system timing specifications: • Stratum 3E, per ITU-T G.813 • Free running accuracy: +/– 4.6 ppm • Holdover stability: 3.7 exp –7/day, including temperature (< 255 slips in first 24 hours) • Reference: External building integrated timing supply (BITS), line, internal A.1.
Appendix A Hardware Specifications A.3 General Card Specifications Table A-1 SFP Specifications SFP Interface Transmitter Output Receiver Input Power Power Min/Max (dBm) Min/Max (dBm) 15454-SFP-LC-SX/ 15454E-SFP-LC-SX Gigabit Ethernet (GE) –9.5 to –4 –17 to 0 15454-SFP-LC-LX/ 15454E-SFP-LC-LX GE –9.5 to –3 –19 to –3 15454-SFP3-1-IR= OC-3 –15 to –8 –23 to –8 15454E-SFP-L.1.1= STM-1 –15 to –8 –34 to –10 15454-SFP12-4-IR= OC-12, D1 Video –15 to –8 –28 to –7 15454E-SFP-L.4.
Appendix A Hardware Specifications A.3.1 Power Consumption Table A-2 Individual Card Power Requirements Card Type Card Name Watts Ampheres BTU/Hr Control Cards TCC2 26.00 0.54 88.8 (0.43 A at –60 V) Electrical Cards Optical Cards TCC2P 27.00 0.56 92.2 XC10G 78.60 1.64 268.4 XC-VXL-10G 81.30 1.69 277.6 XC-VXL-2.5G 81.30 1.69 277.6 AIC-I 8.00 0.17 27.3 Fan Tray –48 VDC 53.00 1.10 181.0 E1-N-14 24.00 0.50 81.9 E1-42 38.10 0.79 130.1 E3-12 44.00 0.92 150.
Appendix A Hardware Specifications A.3.2 Temperature Ranges Table A-2 Individual Card Power Requirements (continued) Card Type Card Name Watts Ampheres BTU/Hr Ethernet Cards E100T-G 65.00 1.35 221.93 E1000-2-G 53.50 1.11 182.67 G1000-4 63.00 (including Gigabit Interface Converters [GBICs]) 1.31 215.11 G1K-4 63.00 (including GBICs) 1.31 215.11 ML100T-12 53.00 1.10 181.0 ML1000-2 49.00 (including SFPs) 1.02 167.3 FC_MR-4 (Fibre Channel) 60 1.25 212.
Appendix A Hardware Specifications A.3.
Appendix A Hardware Specifications A.4 Common Control Card Specifications A.4 Common Control Card Specifications This section provides specifications for the common control cards. For compliance information, refer to the Cisco Optical Transport Products Safety and Compliance Information document. A.4.
Appendix A Hardware Specifications A.4.3 XC10G Card Specifications • CTC software – Interface: EIA/TIA-232 (local craft access, on TCC2P faceplate) – Interface: 10BaseT LAN (on TCC2P faceplate) – Interface: 10BaseT LAN (via backplane, access on the MIC-A/P card) • Synchronization – Stratum 3, per ITU-T G.812 – Free running access: Accuracy +/- 4.6 ppm – Holdover stability: 3.
Appendix A Hardware Specifications A.4.4 XC-VXL-10G Card Specifications – Depth with backplane connector: 235 mm (9.250 in.) – Weight not including clam shell: 0.6 kg (1.5 lb) A.4.4 XC-VXL-10G Card Specifications The XC-VXL-10G card has the following specifications: • Environmental – Operating temperature: –5 to +55 degrees Celsius (+23 to +131 degrees Fahrenheit) – Operating humidity: 5 to 85%, noncondensing – Power consumption: 81.30 W, 1.69 A at –48 V, 277.6 BTU/hr • Dimensions – Height: 321.
Appendix A Hardware Specifications A.4.6 AIC-I Specifications – Severity customer provisionable – Common 32-V output for all alarm-inputs – Each input limited to 2 mA – Termination via MIC-A/P • Alarm outputs – Number of outputs: 4 (user configurable as inputs) – Switched by opto-MOS (metal oxide semiconductor) – Triggered by definable alarm condition – Maximum allowed open circuit voltage: 60 VDC – Maximum allowed closed circuit current: 100 mA – Termination via MIC-A/P • EOW/LOW – ITU-T G.
Appendix A Hardware Specifications A.5 Electrical Card and FMEC Specifications – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Card weight: 1.8 lb (0.82 kg) A.5 Electrical Card and FMEC Specifications This section provides specifications for the electrical and FMEC cards. For compliance information, refer to the Cisco Optical Transport Products Safety and Compliance Information document. A.5.
Appendix A Hardware Specifications A.5.2 E1-42 Card Specifications • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight not including clam shell: 0.8 kg (1.9 lb) A.5.2 E1-42 Card Specifications The E1-42 card has the following specifications: • E1-42 input – Bit rate: 2.048 Mbps +/–50 ppm – Frame format: Unframed, ITU-T G.
Appendix A Hardware Specifications A.5.3 E3-12 Card Specifications – Depth with backplane connector: 235 mm (9.250 in.) – Weight not including clam shell: 0.8 kg (1.9 lb) A.5.3 E3-12 Card Specifications The E3-12 card has the following specifications: • E3-12 input – Bit rate: 34.
Appendix A Hardware Specifications A.5.4 DS3i-N-12 Card Specifications A.5.4 DS3i-N-12 Card Specifications The DS3i-N-12 card has the following specifications: • DS3i-N-12 input – Bit rate: 44.736 Mbps +/–20 ppm – Frame format: ITU-T G.704, ITU-T G.752/DS-3 ANSI T1.107-1988 – Line code: B3ZS – Termination: Unbalanced coaxial cable – Input impedance: 75 ohms +/– 5% – Cable loss: Maximum 137 m (450 ft): 734A, RG59, 728A Maximum 24 m (79 ft): RG179 – AIS: ITU-T G.
Appendix A Hardware Specifications A.5.5 STM1E-12 Card Specifications – Weight not including clam shell: 0.8 kg (1.9 lb) A.5.5 STM1E-12 Card Specifications The STM1E-12 card has the following specifications: • STM1E-12 input – Bit rate: 155.52 Mbps +/–5 ppm for STM-1 or 139.264 Mbps +/–15 ppm for E-4 – Line code: Coded mark inversion (CMI) – E-4 (can be framed or unframed) – Termination: Unbalanced coaxial cable – Input impedance: 75 ohms +/–5% – Cable loss: Up to 12.
Appendix A Hardware Specifications A.5.6 BLANK Card A.5.6 BLANK Card The BLANK card has the following specifications: • Environmental – Operating temperature: –5 to +45 degrees Celsius (+23 to +113 degrees Fahrenheit) – Operating humidity: 5 to 95%, noncondensing – Power consumption: Not applicable • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Weight not including clam shell: 0.2 kg (0.4 lb) A.5.
Appendix A Hardware Specifications A.5.8 FMEC-DS1/E1 Card Specifications – Depth with backplane connector: 98 mm (3.87 in.) – Weight not including clam shell: 0.3 kg (0.7 lb) A.5.8 FMEC-DS1/E1 Card Specifications The FMEC-DS1/E1 card has the following specifications: • FMEC-DS1/E1 input – Bit rate: 2.048 Mbps +/–50 ppm – Line code: HDB-3 – Termination: Balanced twisted-pair cable – Input impedance: 120 ohms +/–5% – Cable loss: Up to 6 dB at 1024 kHz • FMEC-DS1/E1 output – Bit rate: 2.
Appendix A Hardware Specifications A.5.10 FMEC E1-120PROA Card Specifications – Termination: Balanced twisted-pair cable – Input impedance: 120 ohms +/–5% – Cable loss: Up to 6 dB at 1024 kHz • FMEC E1-120NP output – Bit rate: 2.048 Mbps +/–50 ppm – Line code: HDB-3 – Termination: Balanced twisted-pair cable – Input impedance: 120 ohms +/–5% – Pulse shape: ITU-T G.703, Figure 15 and Table 7 – Pulse amplitude: ITU-T G.
Appendix A Hardware Specifications A.5.11 FMEC E1-120PROB Card Specifications – Pulse amplitude: ITU-T G.703, Figure 15 and Table 7 • FMEC E1-120PROA electrical interface – Connectors: Molex 96-pin LFH connectors (21 ports per connector) • Environmental – Operating temperature: –5 to +45 degrees Celsius (+23 to +113 degrees Fahrenheit) – Operating humidity: 5 to 95%, noncondensing – Power consumption: 0.1 W (provided by the E1-42 card), 0.34 BTU/hr • Dimensions – Height: 182 mm (7.165 in.
Appendix A Hardware Specifications A.5.12 E1-75/120 Impedance Conversion Panel Specifications – Width: 32 mm (1.25 in.) – Depth: 92 mm (3.62 in.) – Depth with backplane connector: 98 mm (3.87 in.) – Weight not including clam shell: 0.3 kg (0.7 lb) A.5.12 E1-75/120 Impedance Conversion Panel Specifications The FMEC E1-75/120 impedance conversion panel has the following specifications: • E1-75/120 input – Bit rate: 2.048 Mbps +/–50 ppm – Line code: HDB-3 • E1-75/120 output – Bit rate: 2.
Appendix A Hardware Specifications A.5.13 FMEC-E3/DS3 Card Specifications • FMEC-E3/DS3 output (for E3 signals) – Bit rate: 34.368 Mbps +/–20 ppm – Line code: HDB-3 – Termination: Unbalanced coaxial cable – Output impedance: 75 ohms +/–5% – Pulse shape: ITU-T G.703, Figure 17 – Pulse amplitude: ITU-T G.703, Figure 17 and Table 9 • FMEC-E3/DS3 Input (for DS3 signals) – Bit rate: 44.
Appendix A Hardware Specifications A.5.14 FMEC STM1E 1:1 Card Specifications A.5.14 FMEC STM1E 1:1 Card Specifications The FMEC STM1E 1:1 card has the following specifications: • FMEC STM1E 1:1 input – Bit rate: 155.52 Mbps +/–20 ppm – Line code: CMI – Termination: Unbalanced coaxial cable – Input impedance: 75 ohms +/–5% – Cable loss: Up to 12.7 dB at 78 MHz • FMEC STM1E 1:1 E4 input – Bit rate: 139.
Appendix A Hardware Specifications A.5.15 FMEC-BLANK Card Specifications – Depth: 92 mm (3.62 in.) – Depth with backplane connector: 98 mm (3.87 in.) – Weight not including clam shell: 0.3 kg (0.7 lb) A.5.
Appendix A Hardware Specifications A.5.17 MIC-C/T/P Card Specifications – Width: 32 mm (1.25 in.) – Depth: 92 mm (3.62 in.) – Depth with backplane connector: 98 mm (3.87 in.) – Weight not including clam shell: 0.2 kg (0.5 lb) A.5.17 MIC-C/T/P Card Specifications The MIC-C/T/P card has the following specifications: • Power supply input BATTERY A – System supply voltage: Nominal –48 VDC Tolerance limits: –40.5 to –57.
Appendix A Hardware Specifications A.6 Optical Card Specifications – Weight not including clam shell: 0.2 kg (0.5 lb) A.6 Optical Card Specifications This section provides specifications for the optical cards. For compliance information, refer to the Cisco Optical Transport Products Safety and Compliance Information document. A.6.1 OC3 IR 4/STM1 SH 1310 Card Specifications The OC3 IR 4/STM1 SH 1310 card has the following specifications: • Line – Bit rate: 155.
Appendix A Hardware Specifications A.6.2 OC3 IR/STM1 SH 1310-8 Card Specifications – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight not including clam shell: 0.4 kg (1.0 lb) A.6.2 OC3 IR/STM1 SH 1310-8 Card Specifications The OC3IR/STM1 SH 1310-8 card has the following specifications: • Line – Bit rate: 155.
Appendix A Hardware Specifications A.6.3 OC12 IR/STM4 SH 1310 Card Specifications – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight not including clam shell: 0.4 kg (1.0 lb) A.6.3 OC12 IR/STM4 SH 1310 Card Specifications The OC12 IR/STM4 SH 1310 card has the following specifications: • Line – Bit rate: 622.08 Mbps – Code: Scrambled NRZ – Fiber: 1310-nm single-mode – Loopback modes: Terminal and facility – Connectors: SC – Compliance: ITU-T G.707, ITU-T G.
Appendix A Hardware Specifications A.6.4 OC12 LR/STM4 LH 1310 Card Specifications – Weight not including clam shell: 0.6 kg (1.4 lb) A.6.4 OC12 LR/STM4 LH 1310 Card Specifications The OC12 LR/STM4 LH 1310 card has the following specifications: • Line – Bit rate: 622.08 Mbps – Code: Scrambled NRZ – Fiber: 1310-nm single-mode – Loopback modes: Terminal and facility – Connectors: SC – Compliance: ITU-T G.707, ITU-T G.
Appendix A Hardware Specifications A.6.6 OC12 IR/STM4 SH 1310-4 Card Specifications • Line – Bit rate: 622.08 Mbps – Code: Scrambled NRZ – Fiber: 1550-nm single-mode – Loopback modes: Terminal and facility – Connectors: SC – Compliance: ITU-T G.707, ITU-T G.
Appendix A Hardware Specifications A.6.
Appendix A Hardware Specifications A.6.
Appendix A Hardware Specifications A.6.
Appendix A Hardware Specifications A.6.10 OC192 SR/STM64 IO 1310 Card Specifications – Receiver input wavelength range: 1520 to 1580 nm • Environmental – Operating temperature: –5 to +45 degrees Celsius (+23 to +113 degrees Fahrenheit) – Operating humidity: 5 to 95%, noncondensing – Power consumption: 31.20 W, 0.65 A at –48 V, 106.5 BTU/hr • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.
Appendix A Hardware Specifications A.6.11 OC192 IR/STM64 SH 1550 Card Specifications – Code: Scrambled NRZ – Fiber: 1310-nm single-mode – Maximum chromatic dispersion allowance: 6.6 ps/nm – Loopback modes: Terminal and facility – Connectors: SC – Compliance: ITU-T G.707, ITU-T G.957, ITU-T G.
Appendix A Hardware Specifications A.6.12 OC192 LR/STM64 LH 1550 Card Specifications – Loopback modes: Terminal and facility Note You must use a 3 to 15 dB fiber attenuator (5 dB recommended) when working with the OC192 IR/STM64 SH 1550 card in a loopback. Do not use fiber loopbacks with the OC192 IR/STM64 SH 1550 card. Using fiber loopbacks can cause irreparable damage to the OC192 IR/STM64 SH 1550 card. – Connectors: SC – Compliance: ITU-T G.707, ITU-T G.
Appendix A Hardware Specifications A.6.12 OC192 LR/STM64 LH 1550 Card Specifications – Fiber: 1550-nm single-mode – Maximum chromatic dispersion allowance: 1360 ps/nm Caution You must use a 20 dB fiber attenuator (19 to 24 dB) when working with the OC192 LR/STM64 LH 1550 card in a loopback. Do not use fiber loopbacks with these cards. – Loopback modes: Terminal and facility – Connectors: SC – Compliance: ITU-T G.707, ITU-T G.
Appendix A Hardware Specifications A.6.13 OC192 LR/STM64 LH ITU 15xx.xx Card Specifications – Weight not including clam shell: 1.3 kg (3.1 lb) A.6.13 OC192 LR/STM64 LH ITU 15xx.xx Card Specifications The OC192 LR/STM64 LH ITU 15xx.xx card has the following specifications: • Line – Bit rate: 9.
Appendix A Hardware Specifications A.7 Ethernet Card Specifications – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Depth with backplane connector: 235 mm (9.250 in.) – Weight not including clam shell: 1.3 kg (3.1 lb) • Currently available wavelengths and versions of OC192 LR/STM64 LH ITU 15xx.xx card: ITU grid blue band: – 1534.25 +/– 0.040 nm, OC192 LR/STM64 LH ITU 1534.25 – 1535.04 +/– 0.040 nm, OC192 LR/STM64 LH ITU 1535.04 – 1535.82 +/– 0.
Appendix A Hardware Specifications A.7.2 E1000-2-G Card Specifications – Power consumption: 65 W, 1.35 A, 221.93 BTU/hr • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Card weight: 2.3 lb (1.0 kg) • Compliance – ONS 15454 SDH cards, when installed in a system, comply with these safety standards: UL 1950, CSA C22.2 No. 950, EN 60950, IEC 60950 A.7.
Appendix A Hardware Specifications A.7.4 G1K-4 Card Specifications – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.) – Card weight: 2.1 lb (0.9 kg) A.7.4 G1K-4 Card Specifications The G1K-4 card has the following specifications: • Environmental – Operating temperature: –5 to +55 degrees Celsius (+23 to +131 degrees Fahrenheit) – Operating humidity: 5 to 95%, noncondensing – Power consumption: 63.00 W, 1.31 A at –48 V, 215.1 BTU/hr • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.
Appendix A Hardware Specifications A.7.6 ML1000-2 Card Specifications A.7.6 ML1000-2 Card Specifications The ML1000-2 card has the following specifications: • Environmental – Operating temperature: –5 to +55 degrees Celsius (+23 to +131 degrees Fahrenheit) – Operating humidity: 5 to 95%, noncondensing – Power consumption: 49.00 W, 1.02 A at –48 V, 167.3 BTU/hr • Dimensions – Height: 321.3 mm (12.650 in.) – Width: 18.2 mm (0.716 in.) – Depth: 228.6 mm (9.000 in.
B A P P E N D I X Administrative and Service States This appendix describes the administrative and service states for Cisco ONS 15454 SDH cards, ports, and cross-connects. For circuit state information, see Chapter 10, “Circuits and Tunnels.” Software Release 5.0 states are based on the generic state model defined in Telcordia GR-1093-CORE, Issue 2 and ITU-T X.731. B.1 Service States Service states include a Primary State (PST), a Primary State Qualifier (PSTQ), and one or more Secondary States (SST).
Appendix B Administrative and Service States B.2 Administrative States Table B-2 ONS 15454 SDH Secondary States (continued) Secondary State Definition loopback The entity is in loopback mode. mismatchOfEquipment An improper card is installed, a cross-connect card does not support an installed card, or an incompatible backplane is installed. For example, an installed card is not compatible with the card preprovisioning or the slot. This SST applies only to cards.
Appendix B Administrative and Service States B.3 Service State Transitions B.3 Service State Transitions This section describes the transition from one service state to the next for cards, ports, and cross-connects. A service state transition is based on the action performed on the entity. B.3.1 Card Service State Transitions Table B-4 lists card service state transitions.
Appendix B Administrative and Service States B.3.1 Card Service State Transitions Table B-4 ONS 15454 SDH Card Service State Transitions (continued) Current Service State Action Next Service State Unlocked-disabled,notInstalled Insert a valid card. Unlocked-disabled,softwareDownload Insert an invalid card. Unlocked-disabled,mismatchOfEquipment Delete the card. Locked-disabled,unassigned & notInstalled Change the administrative state to Locked,maintenance.
Appendix B Administrative and Service States B.3.2 Port and Cross-Connect Service State Transitions B.3.2 Port and Cross-Connect Service State Transitions Table B-5 lists the port and cross-connect service state transitions. Port states do not impact cross-connect states with one exception. A cross-connect in the Unlocked-disabled,automaticInService service state cannot transition autonomously into the Unlocked-enabled service state until the parent port is Unlocked-enabled.
Appendix B Administrative and Service States B.3.2 Port and Cross-Connect Service State Transitions Table B-5 ONS 15454 SDH Port and Cross-Connect Service State Transitions (continued) Current Service State Action Next Service State Locked-enabled,disabled Put the port or cross-connect in the Unlocked administrative state. Unlocked-enabled Put the port or cross-connect in the Unlocked,automaticInService administrative state.
C A P P E N D I X Network Element Defaults This appendix describes the factory-configured (default) network element (NE) settings for the Cisco ONS 15454 SDH. It includes descriptions of card, node, and CTC default settings. To import, export, or edit the settings, refer to the “Maintain the Node” chapter of the Cisco ONS 15454 SDH Procedure Guide. Cards supported by this platform that are not listed in this appendix are not supported by factory-configured NE default settings.
Appendix C Network Element Defaults C.2 Card Default Settings Note • Line Coding (E1-42 cards) defines the E-1 transmission coding type that is used. • Line Length (DS3i) defines the distance (in feet) from the FMEC connection to the next termination point. • Line Type (E1, E1-42, and DS3i cards) defines the type of framing used. • Port State (all cards) sets the port to one of the four available states (IS, OOS, OOS_MT, or OOS_AINS), depending on whether you need ports in or out of service.
Appendix C Network Element Defaults C.2.1 E1 Card Default Settings C.2.1 E1 Card Default Settings Table C-1 lists the E1 Card default settings. Table C-1 E1 Card Default Settings Default Name Default Value Minimum Maximum E1.config.AINSSoakTime 0.33333333333 E1.config.LineType E1_MF E1.config.SDBER 1e-007 E1.config.SFBER 0.0001 E1.config.State unlocked, automaticInService E1.pmthresholds.line.nearend.15min.CV 9 0 1388700 E1.pmthresholds.line.nearend.15min.ES 65 0 900 E1.
Appendix C Network Element Defaults C.2.2 E1-42 Card Default Settings Table C-1 E1 Card Default Settings (continued) Default Name Default Value Minimum Maximum E1.pmthresholds.vclo.farend.15min.BBE 15 0 539100 E1.pmthresholds.vclo.farend.15min.EB 18 0 1800000 E1.pmthresholds.vclo.farend.15min.ES 65 0 900 E1.pmthresholds.vclo.farend.15min.SES 10 0 900 E1.pmthresholds.vclo.farend.15min.UAS 10 0 900 E1.pmthresholds.vclo.farend.1day.BBE 150 0 51753600 E1.pmthresholds.vclo.
Appendix C Network Element Defaults C.2.2 E1-42 Card Default Settings Table C-2 E1-42 Card Default Settings (continued) Default Name Default Value Minimum Maximum E1_42.pmthresholds.line.nearend.15min.SES 10 0 900 E1_42.pmthresholds.line.nearend.1day.CV 90 0 133315200 E1_42.pmthresholds.line.nearend.1day.ES 648 0 86400 E1_42.pmthresholds.line.nearend.1day.LOSS 0 0 900 E1_42.pmthresholds.line.nearend.1day.SES 100 0 86400 E1_42.pmthresholds.path.farend.15min.
Appendix C Network Element Defaults C.2.3 E3 Card Default Settings Table C-2 E1-42 Card Default Settings (continued) Default Name Default Value Minimum Maximum E1_42.pmthresholds.vclo.nearend.15min.EB 18 0 1800000 E1_42.pmthresholds.vclo.nearend.15min.ES 65 0 900 E1_42.pmthresholds.vclo.nearend.15min.SES 10 0 900 E1_42.pmthresholds.vclo.nearend.15min.UAS 10 0 900 E1_42.pmthresholds.vclo.nearend.1day.BBE 150 0 51753600 E1_42.pmthresholds.vclo.nearend.1day.
Appendix C Network Element Defaults C.2.3 E3 Card Default Settings Table C-3 E3 Card Default Settings (continued) Default Name Default Value Minimum Maximum E3.pmthresholds.vc4.farend.15min.ES 12 0 900 E3.pmthresholds.vc4.farend.15min.SES 3 0 900 E3.pmthresholds.vc4.farend.15min.UAS 10 0 900 E3.pmthresholds.vc4.farend.1day.BBE 250 0 207273600 E3.pmthresholds.vc4.farend.1day.EB 125 0 691200000 E3.pmthresholds.vc4.farend.1day.ES 100 0 86400 E3.pmthresholds.vc4.farend.1day.
Appendix C Network Element Defaults C.2.4 FC_MR-4 Card Default Settings Table C-3 E3 Card Default Settings (continued) Default Name Default Value Minimum Maximum E3.pmthresholds.vclo.nearend.1day.SES 7 0 86400 E3.pmthresholds.vclo.nearend.1day.UAS 10 0 86400 C.2.4 FC_MR-4 Card Default Settings Table C-4 lists the FC_MR-4 (fibre channel) card default settings. Table C-4 FC-MR Card Default Settings Default Name Default Value FC-MR.config.card.
Appendix C Network Element Defaults C.2.5 DS3I Card Default Settings Table C-5 DS3I Card Default Settings (continued) Default Name Default Value Minimum Maximum DS3I.pmthresholds.cpbitpath.farend.15min.ES 25 0 900 DS3I.pmthresholds.cpbitpath.farend.15min.SAS 2 0 900 DS3I.pmthresholds.cpbitpath.farend.15min.SES 4 0 900 DS3I.pmthresholds.cpbitpath.farend.15min.UAS 10 0 900 DS3I.pmthresholds.cpbitpath.farend.1day.CV 3820 0 27561600 DS3I.pmthresholds.cpbitpath.farend.1day.
Appendix C Network Element Defaults C.2.5 DS3I Card Default Settings Table C-5 DS3I Card Default Settings (continued) Default Name Default Value Minimum Maximum DS3I.pmthresholds.pbitpath.nearend.1day.UAS 10 0 86400 DS3I.pmthresholds.vc4.farend.15min.BBE 25 0 2159100 DS3I.pmthresholds.vc4.farend.15min.EB 15 0 7200000 DS3I.pmthresholds.vc4.farend.15min.ES 12 0 900 DS3I.pmthresholds.vc4.farend.15min.SES 3 0 900 DS3I.pmthresholds.vc4.farend.15min.UAS 10 0 900 DS3I.pmthresholds.
Appendix C Network Element Defaults C.2.6 Data Card Default Settings Table C-5 DS3I Card Default Settings (continued) Default Name Default Value Minimum Maximum DS3I.pmthresholds.vclo.nearend.1day.BBE 150 0 207273600 DS3I.pmthresholds.vclo.nearend.1day.EB 125 0 691200000 DS3I.pmthresholds.vclo.nearend.1day.ES 100 0 86400 DS3I.pmthresholds.vclo.nearend.1day.SES 7 0 86400 DS3I.pmthresholds.vclo.nearend.1day.UAS 10 0 86400 C.2.
Appendix C Network Element Defaults C.2.7 STM1 Card Default Settings Table C-7 STM1 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM1.pmthresholds.ms.farend.15min.UAS 3 0 900 STM1.pmthresholds.ms.farend.1day.BBE 13120 0 13219200 STM1.pmthresholds.ms.farend.1day.EB 13120 0 13219200 STM1.pmthresholds.ms.farend.1day.ES 864 0 86400 STM1.pmthresholds.ms.farend.1day.SES 4 0 86400 STM1.pmthresholds.ms.farend.1day.UAS 10 0 86400 STM1.pmthresholds.ms.
Appendix C Network Element Defaults C.2.8 STM1-8 Card Default Settings Table C-7 STM1 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM1.pmthresholds.path.nearend.15min.PJCS-PDET 100 0 900 STM1.pmthresholds.path.nearend.15min.PJCS-PGEN 100 0 900 STM1.pmthresholds.path.nearend.15min.PPJC-PDET 60 0 7200000 STM1.pmthresholds.path.nearend.15min.PPJC-PGEN 60 0 7200000 STM1.pmthresholds.path.nearend.15min.SES 3 0 900 STM1.pmthresholds.path.nearend.15min.
Appendix C Network Element Defaults C.2.8 STM1-8 Card Default Settings Table C-8 STM1-8 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM1-8.config.line.AlsRecoveryPulseDuration 2 STM1-8.config.line.AlsRecoveryPulseInterval 100 60 300 STM1-8.config.line.PJVC4Mon# 0 0 1 STM1-8.config.line.SDBER 1e-007 STM1-8.config.line.SendDoNotUse FALSE STM1-8.config.line.SendDoNotUse FALSE STM1-8.config.line.SFBER 0.0001 STM1-8.config.line.
Appendix C Network Element Defaults C.2.8 STM1-8 Card Default Settings Table C-8 STM1-8 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM1-8.pmthresholds.path.farend.15min.ES 12 0 900 STM1-8.pmthresholds.path.farend.15min.SES 3 0 900 STM1-8.pmthresholds.path.farend.15min.UAS 10 0 900 STM1-8.pmthresholds.path.farend.1day.BBE 250 0 207273600 STM1-8.pmthresholds.path.farend.1day.EB 125 0 691200000 STM1-8.pmthresholds.path.farend.1day.
Appendix C Network Element Defaults C.2.9 STM1E-12 Card Default Settings Table C-8 STM1-8 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM1-8.pmthresholds.rs.nearend.1day.BBE 100000 0 13305600 STM1-8.pmthresholds.rs.nearend.1day.EB 100000 0 13305600 STM1-8.pmthresholds.rs.nearend.1day.ES 5000 0 86400 STM1-8.pmthresholds.rs.nearend.1day.SES 5000 0 86400 Minimum Maximum C.2.
Appendix C Network Element Defaults C.2.9 STM1E-12 Card Default Settings Table C-9 STM1E-12 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM1E-12.pmthresholds.ms.nearend.15min.stm1.ES 87 0 900 STM1E-12.pmthresholds.ms.nearend.15min.stm1.SES 1 0 900 STM1E-12.pmthresholds.ms.nearend.15min.stm1.UAS 3 0 900 STM1E-12.pmthresholds.ms.nearend.1day.e4.BBE 6300 0 13219200 STM1E-12.pmthresholds.ms.nearend.1day.e4.EB 6300 0 13219200 STM1E-12.pmthresholds.ms.
Appendix C Network Element Defaults C.2.10 STM4 Card Default Settings Table C-9 STM1E-12 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM1E-12.pmthresholds.rs.nearend.15min.SES 500 0 900 STM1E-12.pmthresholds.rs.nearend.15min.UAS 500 0 900 STM1E-12.pmthresholds.rs.nearend.1day.BBE 100000 0 13305600 STM1E-12.pmthresholds.rs.nearend.1day.EB 100000 0 13305600 STM1E-12.pmthresholds.rs.nearend.1day.ES 5000 0 86400 STM1E-12.pmthresholds.rs.nearend.1day.
Appendix C Network Element Defaults C.2.10 STM4 Card Default Settings Table C-10 STM4 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM4.pmthresholds.ms.nearend.15min.ES 87 0 900 STM4.pmthresholds.ms.nearend.15min.PSC 1 0 600 STM4.pmthresholds.ms.nearend.15min.PSC-W 1 0 600 STM4.pmthresholds.ms.nearend.15min.PSD 300 0 900 STM4.pmthresholds.ms.nearend.15min.PSD-W 300 0 900 STM4.pmthresholds.ms.nearend.15min.SES 1 0 900 STM4.pmthresholds.ms.
Appendix C Network Element Defaults C.2.11 STM4-4 Card Default Settings Table C-10 STM4 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM4.pmthresholds.path.nearend.1day.PPJC-PDET 5760 0 691200000 STM4.pmthresholds.path.nearend.1day.PPJC-PGEN 5760 0 691200000 STM4.pmthresholds.path.nearend.1day.SES 7 0 86400 STM4.pmthresholds.path.nearend.1day.UAS 10 0 86400 STM4.pmthresholds.rs.nearend.15min.BBE 10000 0 553500 STM4.pmthresholds.rs.nearend.15min.
Appendix C Network Element Defaults C.2.11 STM4-4 Card Default Settings Table C-11 STM4-4 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM4-4.pmthresholds.ms.farend.1day.ES 864 0 86400 STM4-4.pmthresholds.ms.farend.1day.SES 4 0 86400 STM4-4.pmthresholds.ms.farend.1day.UAS 10 0 86400 STM4-4.pmthresholds.ms.nearend.15min.BBE 5315 0 552600 STM4-4.pmthresholds.ms.nearend.15min.EB 5315 0 552600 STM4-4.pmthresholds.ms.nearend.15min.
Appendix C Network Element Defaults C.2.12 STM16 Card Default Settings Table C-11 STM4-4 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM4-4.pmthresholds.path.nearend.1day.NPJC-PDET 5760 0 691200000 STM4-4.pmthresholds.path.nearend.1day.NPJC-PGEN 5760 0 691200000 STM4-4.pmthresholds.path.nearend.1day.PJCDIFF 5760 0 1382400000 STM4-4.pmthresholds.path.nearend.1day.PJCS-PDET 9600 0 86400 STM4-4.pmthresholds.path.nearend.1day.
Appendix C Network Element Defaults C.2.12 STM16 Card Default Settings Table C-12 STM16 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM16.config.vc4.IPPMEnabled FALSE STM16.pmthresholds.ms.farend.15min.BBE 21260 0 2212200 STM16.pmthresholds.ms.farend.15min.EB 21260 0 2212200 STM16.pmthresholds.ms.farend.15min.ES 87 0 900 STM16.pmthresholds.ms.farend.15min.SES 1 0 900 STM16.pmthresholds.ms.farend.15min.UAS 3 0 900 STM16.pmthresholds.ms.farend.
Appendix C Network Element Defaults C.2.12 STM16 Card Default Settings Table C-12 STM16 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM16.pmthresholds.ms.nearend.1day.UAS 10 0 86400 STM16.pmthresholds.path.nearend.15min.BBE 25 0 2159100 STM16.pmthresholds.path.nearend.15min.EB 15 0 7200000 STM16.pmthresholds.path.nearend.15min.ES 12 0 900 STM16.pmthresholds.path.nearend.15min.NPJC-PDET 60 0 7200000 STM16.pmthresholds.path.nearend.15min.
Appendix C Network Element Defaults C.2.13 STM64 Card Default Settings C.2.13 STM64 Card Default Settings Table C-13 lists the STM64 card default settings. Table C-13 STM64 Card Default Settings Default Name Default Value Minimum Maximum STM64.config.line.AdminSSMIn STU STM64.config.line.AINSSoakTime 0.33333333333 STM64.config.line.AlsMode Disabled STM64.config.line.AlsRecoveryPulseDuration 2 STM64.config.line.AlsRecoveryPulseInterval 100 60 300 STM64.config.line.
Appendix C Network Element Defaults C.2.13 STM64 Card Default Settings Table C-13 STM64 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM64.pmthresholds.ms.nearend.15min.PSD-S 300 0 900 STM64.pmthresholds.ms.nearend.15min.PSD-W 300 0 900 STM64.pmthresholds.ms.nearend.15min.SES 1 0 900 STM64.pmthresholds.ms.nearend.15min.UAS 3 0 900 STM64.pmthresholds.ms.nearend.1day.BBE 850400 0 849657600 STM64.pmthresholds.ms.nearend.1day.
Appendix C Network Element Defaults C.2.14 MXP_2.5G_10G Card Default Settings Table C-13 STM64 Card Default Settings (continued) Default Name Default Value Minimum Maximum STM64.pmthresholds.path.nearend.1day.PJCS-PGEN 9600 0 86400 STM64.pmthresholds.path.nearend.1day.PPJC-PDET 5760 0 691200000 STM64.pmthresholds.path.nearend.1day.PPJC-PGEN 5760 0 691200000 STM64.pmthresholds.path.nearend.1day.SES 7 0 86400 STM64.pmthresholds.path.nearend.1day.UAS 10 0 86400 STM64.pmthresholds.
Appendix C Network Element Defaults C.2.14 MXP_2.5G_10G Card Default Settings Table C-14 MXP-2.5G-10G Card Default Settings (continued) Default Name Default Value Minimum Maximum MXP-2_5G-10G.opticalthresholds.client.alarm.HighRxPower 3 MXP-2_5G-10G.opticalthresholds.client.alarm.HighTxPower 3 MXP-2_5G-10G.opticalthresholds.client.alarm.LowRxPower -21 MXP-2_5G-10G.opticalthresholds.client.alarm.LowTxPower -8 0 9033621811200 MXP-2_5G-10G.otn.fecthresholds.standard.15min.
Appendix C Network Element Defaults C.2.14 MXP_2.5G_10G Card Default Settings Table C-14 MXP-2.5G-10G Card Default Settings (continued) Default Name Default Value Minimum Maximum MXP-2_5G-10G.otn.g709thresholds.pm.farend.15min.SES 1 0 900 MXP-2_5G-10G.otn.g709thresholds.pm.farend.15min.UAS 3 0 900 MXP-2_5G-10G.otn.g709thresholds.pm.farend.1day.BBE 850400 0 849657600 MXP-2_5G-10G.otn.g709thresholds.pm.farend.1day.ES 864 0 86400 MXP-2_5G-10G.otn.g709thresholds.pm.farend.1day.
Appendix C Network Element Defaults C.2.14 MXP_2.5G_10G Card Default Settings Table C-14 MXP-2.5G-10G Card Default Settings (continued) Default Name Default Value Minimum Maximum MXP-2_5G-10G.otn.g709thresholds.sm.nearend.1day.UAS 5000 0 86400 MXP-2_5G-10G.otn.otnLines.FEC Standard MXP-2_5G-10G.otn.otnLines.G709OTN TRUE MXP-2_5G-10G.otn.otnLines.SDBER 1e-007 MXP-2_5G-10G.pmthresholds.client.ms.farend.15min.BBE 21260 0 2212200 MXP-2_5G-10G.pmthresholds.client.ms.farend.15min.
Appendix C Network Element Defaults C.2.15 MXP_2.5G_10E Card Default Settings Table C-14 MXP-2.5G-10G Card Default Settings (continued) Default Name Default Value Minimum Maximum MXP-2_5G-10G.pmthresholds.trunk.ms.farend.15min.ES 87 0 900 MXP-2_5G-10G.pmthresholds.trunk.ms.farend.15min.SES 1 0 900 MXP-2_5G-10G.pmthresholds.trunk.ms.farend.15min.UAS 3 0 900 MXP-2_5G-10G.pmthresholds.trunk.ms.farend.1day.BBE 850400 0 849657600 MXP-2_5G-10G.pmthresholds.trunk.ms.farend.1day.
Appendix C Network Element Defaults C.2.15 MXP_2.5G_10E Card Default Settings Table C-15 MXP-2.5G-10E Card Default Settings Default Name Default Value MXP-2_5G-10E.config.client.AINSSoakTime 0.33333333333 MXP-2_5G-10E.config.client.AisSquelchMode Squelch MXP-2_5G-10E.config.client.AlsMode Disabled MXP-2_5G-10E.config.client.AlsRecoveryPulseDuration 2 MXP-2_5G-10E.config.client.AlsRecoveryPulseInterval 100 MXP-2_5G-10E.config.client.ppmPortAssignment STM16_PORT MXP-2_5G-10E.config.client.
Appendix C Network Element Defaults C.2.15 MXP_2.5G_10E Card Default Settings Table C-15 MXP-2.5G-10E Card Default Settings (continued) Default Name Default Value Minimum Maximum MXP-2_5G-10E.opticalthresholds.trunk.warning.15min.HighLaserBias 95 MXP-2_5G-10E.opticalthresholds.trunk.warning.15min.HighRxPower -7.5 MXP-2_5G-10E.opticalthresholds.trunk.warning.15min.HighTxPower 7 MXP-2_5G-10E.opticalthresholds.trunk.warning.15min.LowRxPower -24.5 MXP-2_5G-10E.opticalthresholds.trunk.warning.
Appendix C Network Element Defaults C.2.15 MXP_2.5G_10E Card Default Settings Table C-15 MXP-2.5G-10E Card Default Settings (continued) Default Name Default Value Minimum Maximum MXP-2_5G-10E.otn.g709thresholds.pm.nearend.15min.UAS 3 0 900 MXP-2_5G-10E.otn.g709thresholds.pm.nearend.1day.BBE 850400 0 849657600 MXP-2_5G-10E.otn.g709thresholds.pm.nearend.1day.ES 864 0 86400 MXP-2_5G-10E.otn.g709thresholds.pm.nearend.1day.FC 40 0 6912 MXP-2_5G-10E.otn.g709thresholds.pm.nearend.1day.
Appendix C Network Element Defaults C.2.16 MXP_MR_2.5G Card Default Settings Table C-15 MXP-2.5G-10E Card Default Settings (continued) Default Name Default Value Minimum Maximum MXP-2_5G-10E.pmthresholds.client.ms.farend.1day.EB 212600 0 212371200 MXP-2_5G-10E.pmthresholds.client.ms.farend.1day.ES 864 0 86400 MXP-2_5G-10E.pmthresholds.client.ms.farend.1day.SES 4 0 86400 MXP-2_5G-10E.pmthresholds.client.ms.farend.1day.UAS 10 0 86400 MXP-2_5G-10E.pmthresholds.client.ms.nearend.15min.
Appendix C Network Element Defaults C.2.16 MXP_MR_2.5G Card Default Settings Table C-16 MXP-MR-2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum 2 256 60 300 MXP-MR-2_5G.config.fc.distanceExtension.AutoadjustGFPBufferThr TRUE eshold MXP-MR-2_5G.config.fc.distanceExtension.AutoDetect TRUE MXP-MR-2_5G.config.fc.distanceExtension.Enabled TRUE MXP-MR-2_5G.config.fc.distanceExtension.NumCredits 32 MXP-MR-2_5G.config.fc.distanceExtension.
Appendix C Network Element Defaults C.2.16 MXP_MR_2.5G Card Default Settings Table C-16 MXP-MR-2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum MXP-MR-2_5G.opticalthresholds.trunk.warning.15min.HighRxPower -7.5 MXP-MR-2_5G.opticalthresholds.trunk.warning.15min.HighTxPower 30 MXP-MR-2_5G.opticalthresholds.trunk.warning.15min.LowRxPower -24.5 MXP-MR-2_5G.opticalthresholds.trunk.warning.15min.LowTxPower -40 MXP-MR-2_5G.opticalthresholds.trunk.warning.1day.
Appendix C Network Element Defaults C.2.17 MXPP_MR_2.5G Card Default Settings Table C-16 MXP-MR-2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum MXP-MR-2_5G.pmthresholds.trunk.rs.nearend.1day.ES 5000 0 86400 MXP-MR-2_5G.pmthresholds.trunk.rs.nearend.1day.SES 5000 0 86400 MXP-MR-2_5G.pmthresholds.trunk.rs.nearend.1day.UAS 5000 0 86400 C.2.17 MXPP_MR_2.5G Card Default Settings Table C-17 lists the MXPP_MR_2.5G card default settings. Table C-17 MXPP-MR-2.
Appendix C Network Element Defaults C.2.17 MXPP_MR_2.5G Card Default Settings Table C-17 MXPP-MR-2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum MXPP-MR-2_5G.opticalthresholds.client.warning.15min.HighR 2 xPower MXPP-MR-2_5G.opticalthresholds.client.warning.15min.HighT 2 xPower MXPP-MR-2_5G.opticalthresholds.client.warning.15min.LowR xPower -20 MXPP-MR-2_5G.opticalthresholds.client.warning.15min.LowT xPower -7 MXPP-MR-2_5G.opticalthresholds.client.warning.1day.
Appendix C Network Element Defaults C.2.17 MXPP_MR_2.5G Card Default Settings Table C-17 MXPP-MR-2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum MXPP-MR-2_5G.opticalthresholds.trunk.warning.1day.LowTxP -40 ower MXPP-MR-2_5G.pmthresholds.trunk.ms.farend.15min.BBE 21260 0 2212200 MXPP-MR-2_5G.pmthresholds.trunk.ms.farend.15min.EB 21260 0 2212200 MXPP-MR-2_5G.pmthresholds.trunk.ms.farend.15min.ES 87 0 900 MXPP-MR-2_5G.pmthresholds.trunk.ms.farend.15min.
Appendix C Network Element Defaults C.2.18 TXP_MR_10E Card Default Settings C.2.18 TXP_MR_10E Card Default Settings Table C-18 lists the TXP_MR_10E card default settings. Table C-18 TXP_MR_10E Card Default Settings Default Name Default Value Minimum TXP-MR-10E.config.client.AINSSoakTime 0.333333333 33 TXP-MR-10E.config.client.AisSquelchMode Squelch TXP-MR-10E.config.client.AlsMode Disabled TXP-MR-10E.config.client.AlsRecoveryPulseDuration 2 TXP-MR-10E.config.client.
Appendix C Network Element Defaults C.2.18 TXP_MR_10E Card Default Settings Table C-18 TXP_MR_10E Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-10E.opticalthresholds.client.warning.1day.HighTxPower 1.5 TXP-MR-10E.opticalthresholds.client.warning.1day.LowRxPower -16.5 TXP-MR-10E.opticalthresholds.client.warning.1day.LowTxPower -8.5 TXP-MR-10E.opticalthresholds.trunk.alarm.HighLaserBias 98 TXP-MR-10E.opticalthresholds.trunk.alarm.
Appendix C Network Element Defaults C.2.18 TXP_MR_10E Card Default Settings Table C-18 TXP_MR_10E Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-10E.otn.g709thresholds.pm.farend.1day.FC 40 0 6912 TXP-MR-10E.otn.g709thresholds.pm.farend.1day.SES 4 0 86400 TXP-MR-10E.otn.g709thresholds.pm.farend.1day.UAS 10 0 86400 TXP-MR-10E.otn.g709thresholds.pm.nearend.15min.BBE 85040 0 8850600 TXP-MR-10E.otn.g709thresholds.pm.nearend.15min.
Appendix C Network Element Defaults C.2.18 TXP_MR_10E Card Default Settings Table C-18 TXP_MR_10E Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-10E.otn.otnLines.G709OTN TRUE TXP-MR-10E.otn.otnLines.SDBER 1e-007 TXP-MR-10E.pmthresholds.client.ms.farend.15min.BBE 85040 0 8850600 TXP-MR-10E.pmthresholds.client.ms.farend.15min.EB 85040 0 8850600 TXP-MR-10E.pmthresholds.client.ms.farend.15min.ES 87 0 900 TXP-MR-10E.pmthresholds.client.ms.farend.15min.
Appendix C Network Element Defaults C.2.19 TXP_MR_10G Card Default Settings Table C-18 TXP_MR_10E Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-10E.pmthresholds.trunk.ms.farend.15min.UAS 3 0 900 TXP-MR-10E.pmthresholds.trunk.ms.farend.1day.BBE 850400 0 849657600 TXP-MR-10E.pmthresholds.trunk.ms.farend.1day.EB 850400 0 849657600 TXP-MR-10E.pmthresholds.trunk.ms.farend.1day.ES 864 0 86400 TXP-MR-10E.pmthresholds.trunk.ms.farend.1day.
Appendix C Network Element Defaults C.2.19 TXP_MR_10G Card Default Settings Table C-19 TXP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-10G.config.client.AlsRecoveryPulseInterval 100 100 300 TXP-MR-10G.config.client.mrPortAssignment UNASSIGNED TXP-MR-10G.config.client.SDBER 1e-007 TXP-MR-10G.config.client.SFBER 0.0001 TXP-MR-10G.config.client.TerminationMode Transparent TXP-MR-10G.config.trunk.AINSSoakTime 0.33333333333 TXP-MR-10G.config.
Appendix C Network Element Defaults C.2.19 TXP_MR_10G Card Default Settings Table C-19 TXP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-10G.opticalthresholds.trunk.warning.1day.HighLaserBias 85.5 TXP-MR-10G.opticalthresholds.trunk.warning.1day.HighRxPower -7.3 TXP-MR-10G.opticalthresholds.trunk.warning.1day.HighTxPower 3.7 TXP-MR-10G.opticalthresholds.trunk.warning.1day.LowRxPower -24.7 TXP-MR-10G.opticalthresholds.trunk.warning.1day.
Appendix C Network Element Defaults C.2.19 TXP_MR_10G Card Default Settings Table C-19 TXP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-10G.otn.g709thresholds.sm.farend.1day.BBE 100000 0 849657600 TXP-MR-10G.otn.g709thresholds.sm.farend.1day.ES 5000 0 86400 TXP-MR-10G.otn.g709thresholds.sm.farend.1day.FC 40 0 6912 TXP-MR-10G.otn.g709thresholds.sm.farend.1day.SES 5000 0 86400 TXP-MR-10G.otn.g709thresholds.sm.farend.1day.
Appendix C Network Element Defaults C.2.19 TXP_MR_10G Card Default Settings Table C-19 TXP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-10G.pmthresholds.client.ms.nearend.1day.SES 4 0 86400 TXP-MR-10G.pmthresholds.client.ms.nearend.1day.UAS 10 0 86400 TXP-MR-10G.pmthresholds.client.rs.nearend.15min.BBE 10000 0 8850600 TXP-MR-10G.pmthresholds.client.rs.nearend.15min.EB 10000 0 7967700 TXP-MR-10G.pmthresholds.client.rs.nearend.15min.
Appendix C Network Element Defaults C.2.20 TXP_MR_2.5G Card Default Settings Table C-19 TXP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-10G.pmthresholds.trunk.rs.nearend.15min.UAS 500 0 900 TXP-MR-10G.pmthresholds.trunk.rs.nearend.1day.BBE 100000 0 849657600 TXP-MR-10G.pmthresholds.trunk.rs.nearend.1day.EB 100000 0 764899200 TXP-MR-10G.pmthresholds.trunk.rs.nearend.1day.ES 5000 0 86400 TXP-MR-10G.pmthresholds.trunk.rs.nearend.1day.
Appendix C Network Element Defaults C.2.20 TXP_MR_2.5G Card Default Settings Table C-20 TXP_MR_2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-2_5G.opticalthresholds.client.warning.15min.LowRxPower -20 TXP-MR-2_5G.opticalthresholds.client.warning.15min.LowTxPower -7 TXP-MR-2_5G.opticalthresholds.client.warning.1day.HighLaserBias 85.5 TXP-MR-2_5G.opticalthresholds.client.warning.1day.HighRxPower 2.5 TXP-MR-2_5G.opticalthresholds.client.warning.1day.
Appendix C Network Element Defaults C.2.20 TXP_MR_2.5G Card Default Settings Table C-20 TXP_MR_2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-2_5G.otn.fecthresholds.2gfiberchannel.15min.Uncorrectable 1 Words 0 4724697600 TXP-MR-2_5G.otn.fecthresholds.2gfiberchannel.1day.BitErrorsCorrec 17366400 ted 0 86722769387520 0 TXP-MR-2_5G.otn.fecthresholds.2gfiberchannel.1day.Uncorrectable Words 96 0 453570969600 TXP-MR-2_5G.otn.fecthresholds.2gficon.15min.
Appendix C Network Element Defaults C.2.20 TXP_MR_2.5G Card Default Settings Table C-20 TXP_MR_2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-2_5G.otn.g709thresholds.pm.nearend.15min.FC 10 0 72 TXP-MR-2_5G.otn.g709thresholds.pm.nearend.15min.SES 1 0 900 TXP-MR-2_5G.otn.g709thresholds.pm.nearend.15min.UAS 3 0 900 TXP-MR-2_5G.otn.g709thresholds.pm.nearend.1day.BBE 212600 0 849657600 TXP-MR-2_5G.otn.g709thresholds.pm.nearend.1day.
Appendix C Network Element Defaults C.2.20 TXP_MR_2.5G Card Default Settings Table C-20 TXP_MR_2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-2_5G.pmthresholds.stm1.ms.farend.1day.BBE 13120 0 13219200 TXP-MR-2_5G.pmthresholds.stm1.ms.farend.1day.EB 13120 0 13219200 TXP-MR-2_5G.pmthresholds.stm1.ms.farend.1day.ES 864 0 86400 TXP-MR-2_5G.pmthresholds.stm1.ms.farend.1day.SES 4 0 86400 TXP-MR-2_5G.pmthresholds.stm1.ms.farend.1day.
Appendix C Network Element Defaults C.2.20 TXP_MR_2.5G Card Default Settings Table C-20 TXP_MR_2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-2_5G.pmthresholds.stm16.ms.nearend.15min.EB 21260 0 2212200 TXP-MR-2_5G.pmthresholds.stm16.ms.nearend.15min.ES 87 0 900 TXP-MR-2_5G.pmthresholds.stm16.ms.nearend.15min.SES 1 0 900 TXP-MR-2_5G.pmthresholds.stm16.ms.nearend.15min.UAS 3 0 900 TXP-MR-2_5G.pmthresholds.stm16.ms.nearend.1day.
Appendix C Network Element Defaults C.2.21 TXPP_MR_10G Card Default Settings Table C-20 TXP_MR_2.5G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXP-MR-2_5G.pmthresholds.stm4.ms.nearend.1day.ES 864 0 86400 TXP-MR-2_5G.pmthresholds.stm4.ms.nearend.1day.SES 4 0 86400 TXP-MR-2_5G.pmthresholds.stm4.ms.nearend.1day.UAS 10 0 86400 TXP-MR-2_5G.pmthresholds.stm4.rs.nearend.15min.BBE 10000 0 553500 TXP-MR-2_5G.pmthresholds.stm4.rs.nearend.15min.
Appendix C Network Element Defaults C.2.21 TXPP_MR_10G Card Default Settings Table C-21 TXPP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXPP-MR-2_5G.config.trunk.SDBER 1e-007 TXPP-MR-2_5G.config.trunk.SFBER 0.0001 TXPP-MR-2_5G.opticalthresholds.client.alarm.HighLaserBias 90 TXPP-MR-2_5G.opticalthresholds.client.alarm.HighRxPower 3 TXPP-MR-2_5G.opticalthresholds.client.alarm.HighTxPower 3 TXPP-MR-2_5G.opticalthresholds.client.alarm.
Appendix C Network Element Defaults C.2.21 TXPP_MR_10G Card Default Settings Table C-21 TXPP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXPP-MR-2_5G.otn.fecthresholds.1gfiberchannel.1day.BitErrorsCorrected 8640000 0 8672276938 75200 TXPP-MR-2_5G.otn.fecthresholds.1gfiberchannel.1day.UncorrectableWords 96 0 4535709696 00 TXPP-MR-2_5G.otn.fecthresholds.1gficon.15min.BitErrorsCorrected 90000 0 9033621811 200 TXPP-MR-2_5G.otn.fecthresholds.1gficon.
Appendix C Network Element Defaults C.2.21 TXPP_MR_10G Card Default Settings Table C-21 TXPP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXPP-MR-2_5G.otn.fecthresholds.stm4.15min.UncorrectableWords 1 0 4724697600 TXPP-MR-2_5G.otn.fecthresholds.stm4.1day.BitErrorsCorrected 5419872 0 8672276938 75200 TXPP-MR-2_5G.otn.fecthresholds.stm4.1day.UncorrectableWords 96 0 4535709696 00 TXPP-MR-2_5G.otn.g709thresholds.pm.farend.15min.
Appendix C Network Element Defaults C.2.21 TXPP_MR_10G Card Default Settings Table C-21 TXPP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXPP-MR-2_5G.otn.g709thresholds.sm.nearend.15min.FC 10 0 72 TXPP-MR-2_5G.otn.g709thresholds.sm.nearend.15min.SES 500 0 900 TXPP-MR-2_5G.otn.g709thresholds.sm.nearend.15min.UAS 500 0 900 TXPP-MR-2_5G.otn.g709thresholds.sm.nearend.1day.BBE 100000 0 849657600 TXPP-MR-2_5G.otn.g709thresholds.sm.nearend.1day.
Appendix C Network Element Defaults C.2.21 TXPP_MR_10G Card Default Settings Table C-21 TXPP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXPP-MR-2_5G.pmthresholds.stm1.rs.nearend.1day.BBE 10000 0 13305600 TXPP-MR-2_5G.pmthresholds.stm1.rs.nearend.1day.EB 100000 0 13305600 TXPP-MR-2_5G.pmthresholds.stm1.rs.nearend.1day.ES 5000 0 86400 TXPP-MR-2_5G.pmthresholds.stm1.rs.nearend.1day.SES 5000 0 86400 TXPP-MR-2_5G.pmthresholds.stm1.rs.nearend.1day.
Appendix C Network Element Defaults C.2.21 TXPP_MR_10G Card Default Settings Table C-21 TXPP_MR_10G Card Default Settings (continued) Default Name Default Value Minimum Maximum TXPP-MR-2_5G.pmthresholds.stm4.ms.farend.15min.EB 5315 0 552600 TXPP-MR-2_5G.pmthresholds.stm4.ms.farend.15min.ES 87 0 900 TXPP-MR-2_5G.pmthresholds.stm4.ms.farend.15min.SES 1 0 900 TXPP-MR-2_5G.pmthresholds.stm4.ms.farend.15min.UAS 3 0 900 TXPP-MR-2_5G.pmthresholds.stm4.ms.farend.1day.
Appendix C Network Element Defaults C.2.22 OSCM Card Default Settings C.2.22 OSCM Card Default Settings Table C-22 lists the OSCM card default settings. Table C-22 OSCM Card Default Settings Default Name Default Value Minimum Maximum OSCM.pmthresholds.ms.farend.15min.BBE 1312 0 137700 OSCM.pmthresholds.ms.farend.15min.EB 1312 0 137700 OSCM.pmthresholds.ms.farend.15min.ES 87 0 900 OSCM.pmthresholds.ms.farend.15min.SES 1 0 900 OSCM.pmthresholds.ms.farend.15min.UAS 3 0 900 OSCM.
Appendix C Network Element Defaults C.2.23 OSC-CSM Card Default Settings C.2.23 OSC-CSM Card Default Settings Table C-23 lists the OSC_CSM card default settings. Table C-23 OSC-CSM Card Default Settings Default Name Default Value Minimum Maximum OSC_CSM.pmthresholds.ms.farend.15min.BBE 1312 0 137700 OSC_CSM.pmthresholds.ms.farend.15min.EB 1312 0 137700 OSC_CSM.pmthresholds.ms.farend.15min.ES 87 0 900 OSC_CSM.pmthresholds.ms.farend.15min.SES 1 0 900 OSC_CSM.pmthresholds.ms.farend.
Appendix C Network Element Defaults C.3 Node Default Settings C.3 Node Default Settings Table C-24 lists the Cisco ONS 15454 SDH node-level default settings for the Cisco ONS 15454 SDH. Cisco provides the following types of settings preprovisioned for each Cisco ONS 15454 SDH node: Table C-24 • SNCP settings determine whether SNCP circuits have SD BER and SF BER monitoring enabled, are revertive, and what the reversion time is.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-24 Node Default Settings (continued) Default Name Default Value NODE.circuits.sncp.Revertive FALSE NODE.circuits.State unlocked, automaticInService NODE.general.DefaultsDescription Factory Defaults NODE.general.IIOPListenerPort 57790 NODE.general.NtpSntpServer 0.0.0.0 NODE.general.TimeZone (GMT-08:00) Pacific Time (US & Canada), Tijuana NODE.general.UseDST TRUE NODE.network.general.
Appendix C Network Element Defaults C.3 Node Default Settings Table C-24 Node Default Settings (continued) Default Name Default Value Minimum Maximum NODE.security.idleUserTimeout.Provisioning 0.020833333333 NODE.security.idleUserTimeout.Retrieve 0 NODE.security.idleUserTimeout.Superuser 0.010416666667 NODE.security.legalDisclaimer.LoginWarningMessage
WARNINGThis system is restricted to authorized users for business purposes.Appendix C Network Element Defaults C.4 CTC Default Settings Table C-24 Node Default Settings (continued) Default Name Default Value NODE.timing.bits-1.AdminSSMIn STU NODE.timing.bits-1.AISThreshold G812L NODE.timing.bits-1.Coding HDB3 NODE.timing.bits-1.CodingOut HDB3 NODE.timing.bits-1.FacilityType E1 NODE.timing.bits-1.FacilityTypeOut E1 NODE.timing.bits-1.Framing FAS+CAS+CRC NODE.timing.bits-1.FramingOut FAS+CAS+CRC NODE.timing.bits-1.Sa bit 4 NODE.timing.bits-1.
Appendix C Network Element Defaults C.4 CTC Default Settings Table C-25 CTC Default Settings Default Name Default Value CTC.circuits.AutoRoute TRUE CTC.circuits.CreateLikeTL1 FALSE CTC.network.Map United States Cisco ONS 15454 SDH Reference Manual, R5.
Appendix C Network Element Defaults C.4 CTC Default Settings Cisco ONS 15454 SDH Reference Manual, R5.
I N D EX specifications Numerics 1+1 optical card protection creating linear ADMs description 11-28 temperature range A-6 user data channel 2-20 air filter 7-4 description 1:1 electrical card protection 7-1 1:N electrical card protection 7-2 A-10 1-14 requirement 1-13 alarm profiles 802.3ad link aggregation. See IEEE 802.3ad link aggregation 802.3z flow control. See IEEE 802.
Index retrieving history 1:0 electrical.
Index shared packet ring types on cards 10-21 shared packet ring Ethernet circuit status 14-22 cost 10-4 types of unidirectional 12-8 8-6 cross-connect 10-21 unidirectional with multiple drops user-defined names for E-Series Ethernet 10-12 14-23 See circuits 10-1 See XC10G card 10-22 circuit states 8-6 craft connection 10-1 VCAT corporate LAN 1-16 See XC-VXL-10G card 10-5 Cisco Transport Controller. See CTC See XC-VXL-2.5G card CMS. See CTC CTC coaxial.
Index defined software compatibility 10-10 definition load balancing SDH specifications 10-10 dual GNEs 10-10 tunneling DCS 2-7 E destination E1000-2-G card 12-4 block diagram routing table 12-23 10-17 12-3 digital cross connect systems.
Index description faceplate enterprise LAN.
Index extended SNCP firewalls 11-29 MS-SPRing bandwidth reuse MS-SPRing subtending MS-SPRing network timing 11-28 two-fiber MS-SPRing 11-10 for foreign terminations setting up 11-29 external alarms input flow control 13-15 13-15 external controls 12-28 14-3, 14-12 connectors 1-8 description 1-7 ports 2-18, 13-15 1-8 1-8 power requirements 13-15 external switching commands external timing 12-27 12-27 line rates description 12-16, 12-17 FMEC 2-18 provisioning output proxy
Index FMEC E1-120PROB card block diagram faceplate description faceplate 3-24 A-20 temperature range A-7 FMEC-E1 card description faceplate specifications 5-8 5-2 A-40 5-9 compatible GBICs A-6 description 3-28 faceplate 3-28 LEDs 3-28 temperature range 5-15 block diagram 5-9 5-10 5-10 software compatibility specifications 3-29 5-2 A-41 gateway 3-29 default 3-29 12-3, 12-6 on routing table A-23 foreign node connection (figure) 12-29 12-23 Proxy ARP-enabled 12-4 four-
Index GNE.
Index line timing ML1000-2 card 9-7 link aggregation link integrity compatible SFPs 14-4 cross-connect compatibility 14-4 load balancing 5-15 description 10-10 local craft pin connections faceplate 1-14 Locked,disabled administrative state LEDs B-2 5-12 5-13 5-13 Locked,maintenance administrative state B-2 port status Locked,outOfGroup administrative state B-2 slot compatibility 5-14 5-14 Locked-disabled service state B-1 software compatibility Locked-enabled service state B-
Index ring switching 11-8 block diagram span switching 11-7 description subtending from an MS-SPRing two-fiber description multicast 4-17 4-18 4-20 port status 11-10 4-20 software compatibility 14-10 specifications 14-1 multiple drops faceplate LEDs 11-2 two-fiber ring example multicard EtherSwitch 11-28 A-30 block diagram description faceplate N LEDs 4-11 4-11 4-11 4-12 port status 8-3 4-12 software compatibility network element defaults node settings specifications C-68
Index specifications faceplate A-35 OC192 LR/STM64 LH 1550 card block diagram description faceplate LEDs specifications description 4-38 specifications 4-4 block diagram LEDs faceplate 4-41 4-4 block diagram 4-4 4-4 A-31 4-25 4-23 4-24 4-25 port status 4-26 software compatibility A-34 block diagram specifications open GNE 4-9 4-4 A-32 12-27 Open Shortest Path First. See OSPF 4-7 optical protection.
Index alternative to static routes definition trunk/trunk card combinations 12-7 provisioning, documenting 12-9 to 12-11 enabled (figure) 13-1 Proxy ARP 12-10 not enabled (figure) 12-23 description 12-11 outOfGroup secondary service state 12-1 enable an ONS 15454 SDH gateway B-2 use with static routes 12-4 12-5 proxy server P firewall filtering rules partial service state path signal label path trace gateway settings 10-6 12-16, 12-17 12-13 GNE and ENE settings 10-15 12-14 GN
Index RJ-45 port. See TCC2 card or TCC2P card shortest path RMON single-card EtherSwitch Ethernet alarm thresholds routing table 14-23 12-23 11-2 14-11 slots card requirements 1-15 FMEC symbols on 1-8 physical description S 1-15 SNCP safety information and Ethernet 1-xxxii to ?? 10-20 SAN card.
Index SST access to nodes B-1 ST3 clock 12-8 destination host or network 9-7 state 12-23 subnetwork connection protection rings. See SNCP administrative subtending rings B-2 card state transitions switching, revertive B-3 cross-connect state transitions port state transitions service Sw-LCAS B-5 7-3 6-4, 10-23 synchronization status messaging.
Index installed software LEDs 2-9 ports 12-25 soft reset 8-1 U unassigned secondary service state unicast 8-15 software compatibility specifications third-party equipment 14-1 Unlocked,automaticInservice administrative state 2-2 Unlocked administrative state A-8 temperature range B-2 B-2 B-2 A-6 Unlocked-disabled service state B-1 1-1, 10-10 Unlocked-enabled service state B-1 user. See security thresholds MIBs user data channel 14-23 2-20 user-defined alarms timing BITS.
Index card view 8-13 cross-connect compatibility cross-connect matrix described LEDs 2-11 10-9 description faceplate 2-3 2-10 2-11 2-12 overview 2-10 software compatibility specifications 2-3 A-9 temperature range A-6 XC-VXL-10G card card view 8-13 cross-connect compatibililty cross-connect matrix described LEDs 2-13 10-10 description faceplate 2-3 2-12 2-13 2-14 software compatibility specifications 2-3 A-10 temperature ranges A-6 XC-VXL-2.